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AHA, ACC Change in Requirement for Surgical Support: Class IIb -> Class III, Level of Evidence A: Supports Nonemergent PCI without Surgical Backup (Change of class IIb, Level of Evidence B).
Larry H Bernstein, MD, FCAP, Author, Curator, Volumes 1,2,3,4,5,6 Co-Editor and Author, Volume Two & Five, Co-Editor and Justin Pearlman, MD, PhD, FACC, Content Consultant to Six-Volume e-SERIES A: Cardiovascular Diseases
Article ID #68: AHA, ACC Change in Requirement for Surgical Support for PCI Performance: Class IIb -> Class III, Level of Evidence A: Support Nonemergent PCI without Surgical Backup (Change of class IIb, Level of evidence B). Published on 7/17/2013
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Voice of content consultant: Justin Pearlman, MD, PhD, FACC
The American Heart Association (AHA) and the American College of Cardiology (ACC) have convened teams of experts to summarize evidence and opinion regarding a wide range of decisions relevant to cardiovascular disease. The system accounts for some of the short comings of “evidence based medicine” by allowing for expert opinion in areas where evidence is not sufficient. The main argument for evidence-based medicine is the existence of surprises, where a plausible decision does not actually appear to work as desired when it is tested. A major problem with adhesion to evidence based medicine is that it can impede adaptation to individual needs (we are all genetically and socially/environmentally unique) and impede innovation. Large studies carry statistical weight but do not necessary consider all relevant factors. Commonly, the AFFIRM trial is interpreted as support that rate control suffices for most atrial fibrillation (AFIB), but half of those randomized to rhythm control were taken off anticoagulation without teaching patients to check their pulse daily for recurrence of AFIB. Thus the endorsed “evidence” may have more to do with the benefits of anticoagulation for both persisting and recurring AFIB and rhythm control may yet prove better than rate control. However, with wide acceptance of a particular conclusion, randomizing to another treatment may be deemed unethical, or may simply not get a large trial due to lack of economic incentive, leaving only the large trial products as the endorsed options. A medication without patent protection, such as bismuth salts for H Pylori infection, lacks financial backing for large trials.
A Scientific Statement From the American Heart Association Committee on Cardiovascular Imaging and Intervention, Council on Cardiovascular Radiology and Intervention, and Committee on Cardiac Imaging, Council on Clinical Cardiology
Reported by Chris Kaiser, Cardiology Editor, MedPage 7/2013
Action Points
Patients with indications for nonemergency PCI who presented at hospitals without on-site cardiac surgery, were randomly assigned to undergo PCI at a hospital without on-site cardiac surgery or at a hospital with on-site cardiac surgery.
The rates of death, myocardial infarction, repeat revascularization, and stroke did not differ significantly between the groups.
Community hospitals without surgical services can safely perform percutaneous coronary intervention (PCI) in low-risk patients — and not refuse higher-risk patients either, the MASS COMM trial found.
Summary
The co-primary endpoint of major adverse cardiac events (MACE) at 30 days occurred at a rate of 9.5% in the 10 hospitals without surgical backup versus 9.4% in the seven hospitals with onsite surgery (P<0.001 for noninferiority), Alice K. Jacobs, MD, of Boston University School of Medicine, and colleagues found.
The other co-primary endpoint of MACE at 12 months was also significant, occurring in 17.3% of patients in hospitals without backup versus 17.8% in centers with surgical services (P<0.001 for non-inferiority), they reported in the study published online by the New England Journal of Medicine. The findings were also reported at the American College of Cardiology meeting.
Study Characteristics and Results
Primary Endpoints
death
myocardial infarction
repeat revascularization
stroke
no significant differences between the two groups at 30 days and at 12 months.
Rate of stent thrombosis at 30 days
similar in both groups (0.6% versus 0.8%) and at 12 months (1.1% versus 2.1%).
Jacobs and colleagues noted that the 2011 PCI guidelines lacked evidence to fully support nonemergent PCI without surgical backup (class IIb, level of evidence B).
CPORT – E trial
Even though those guidelines came out before the results of the CPORT-E trial were published, CPORT-E trial showed similar non-inferiority at 9 months between centers that perform PCI with or without surgical backup in a cohort of nearly 19,000 non-emergent patients. The CPORT-E results were published in the March 2012 issue of the New England Journal of Medicine, and in May three cardiology organizations published an update to cath lab standards allowing for PCI without surgical.
MASS COMM study
To further the evidence, Jacobs and colleagues in 2006 had designed and carried out the Randomized Trial to Compare Percutaneous Coronary Intervention between Massachusetts Hospitals with Cardiac Surgery On-Site and Community Hospitals without Cardiac Surgery On-Site (MASS COMM) in collaboration with the Massachusetts Department of Public Health who collaborated to obtain “evidence on which to base regulatory policy decisions about performing non-emergent PCI in hospitals without on-site cardiac surgery.”
Hospitals without backup surgery were required to perform at least 300 diagnostic catheterizations per year, and operators were mandated to have performed a minimum of 75 PCI procedures per year.
The researchers randomized 3,691 patients to each arm in a 3:1 ratio (without/with backup). The median follow-up was about 1 year.
The median age of patients was 64, one-third were women, and 92% were white. Both groups had similar median ejection fractions at baseline (55%).
The mean number of vessels treated was 1.17 and most patients (84%) had one vessel treated. The mean number of lesions treated was 1.45 and most patients (67%) had one lesion treated.
The indications for PCI were:
1. ST-segment elevated MI (>72 hours before PCI of infarct-related or non–infarct-related artery — 19% and 17%
2. Unstable angina — 45% and 47%
3. Stable angina — 27% and 28%
4. Silent ischemia — 5% and 6%
5. Other — 2.5% and 2.8%
Regarding secondary endpoints, both groups had similar rates of emergency CABG and urgent or emergent PCI at 30 days. Results at 30 days and 12 months were similar for rates of ischemia-driven target-vessel revascularization and target-lesion revascularization. Other endpoints as well were similar at both time points, including
all-cause death
repeat revascularization
stroke
definite or probable stent thrombosis
major vascular complications
Researchers adjusted for a 1.3 greater chance of MACE occurring at a randomly selected hospital compared with another randomly selected hospital and found
the relative risks at 30 days and 12 months “were consistent with those of the primary results” (RR 1.02 and 0.98, respectively).
However, they cautioned that new sites perhaps should be monitored as they gain experience.
A prespecified angiographic review of 376 patients who were in the PCI-without-backup arm and 87 in the other arm showed no differences in
rates of procedural success,
proportion with complete revascularization, or
the proportion of guideline-indicated appropriate lesions for PCI.
Such results show consistent practice patterns between the groups, they noted.
The study had several limitations including the
loss of data for 13% of patients, the
exclusion of some patients for certain clinical and anatomical features, and
not having the power to detect non-inferiority in the separate components of the primary endpoint, researchers wrote.
A simple calculation of patient variables before PCI may help stem the tide of readmission within the first month. Also this week, two blood pressure drugs that benefit diabetics and imaging cardiac sympathetic innervation.
Pre-PCI Factors Predict Return Trip
A new 30-day readmission risk prediction model for patients undergoing percutaneous coronary intervention (PCI) showed it’s possible to predict risk using only variables known before PCI, according to a study published online in Circulation: Cardiovascular Quality and Outcomes.
After multivariable adjustment, the 10 pre-PCI variables that predicted 30-day readmission were older age (mean age 68 in this study), female sex, insurance type (Medicare, state, or unknown), GFR category (less than 30 and 30-60 mL/min per 1.73m2), current or history of heart failure, chronic lung disease, peripheral vascular disease, cardiogenic shock at presentation, admit source (acute and non-acute care facility or emergency department), and previous coronary artery bypass graft surgery.
Additional significant variables post-discharge that predicted 30-day readmission were beta-blocker prescribed at discharge, post-PCI vascular or bleeding complications, discharge location, African American race, diabetes status and modality of treatment, any drug-eluting stent during the index procedure, and extended length of stay.
Vascular Surgery: International, Multispecialty Position Statement on Carotid Stenting, 2013 and Contributions of a Vascular Surgeon at Peak Career – Richard Paul Cambria, MD
Author and Curator: Aviva Lev-Ari, PhD, RN
Article ID #66: Vascular Surgery: International, Multispecialty Position Statement on Carotid Stenting, 2013 and Contributions of a Vascular Surgeon at Peak Career – Richard Paul Cambria, MD. Published on 7/14/2013
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Part One:
Vascular Surgery International, Multispecialty Position Statement on Carotid Stenting, 2013
Part Two:
Contributions of a Vascular Surgeon at Peak Career – Richard Paul Cambria, MD, Chief, Division of Vascular and Endovascular Surgery Co-Director, Thoracic Aortic Center @ MGH
I. Recollection of a visit at Dr. Cambria’s Office, 2004
II. Shadowing Dr. Cambria in OR @MGH
III. Dr. Cambria: Selection of Contributions to Scientific Research on Vascular Surgery
IV. Cardiovascular Clinical Observational Experience – Aviva Lev-Ari, PhD, RN
V. Cases with Complications: CEA and CAS
Part Three:
On 8/1/2013, Cleveland Clinic Reports Equivalence between carotid endarterectomy (CEA) and open-heart surgery (OHS) and carotid artery stenting (CAS) followed by coronary artery bypass graft (CABG) surgery or non-CABG cardiac surgery
Part One:
Vascular Surgery International, Multispecialty Position Statement on Carotid Stenting, 2013 Part
No other invasive intervention procedure in the history of Vascular Surgery has stormed the profession more than the two treatment options for carotid artery partial to complete blockage than Carotid endarterectomy (CEA) and Carotid angioplasty and stenting (CAS).
The debate required evidence based resolution for the two treatment options in terms of patient outcomes and adverse events. As the title of the Position statement explained below, the verdict is non equivocal: Routine Carotid Stenting is inferior to Carotid endarterectomy (CEA) from a patient safety and outcomes.
In conclusion, current global evidence shows that, even in the best academic centers, CAS is less effective (causing more strokes) and more expensive than CEA. It is premature that some guidelines have recently added support for routine practice CAS as an alternative to CEA for
asymptomatic43,44 and
low/ average surgical risk symptomatic patients43–45
because CAS may easily be misinterpreted by readers as being equivalent for
stroke prevention46 and
historical procedural standards were cited.
CAS, for these patients, should still only be performed and paid for within well‐designed, adequately powered trials. The US Center for Medicare and Medicaid Services is doing its job and setting an excellent global example. It is protecting Medicare beneficiaries from routine practice procedures, which are currently more likely to harm them and waste finite resources47 that could be used for their advantage. Meanwhile, we need to reassess the current routine practice role of CEA and deliver optimal current medical treatment to all who need it.
Clinical Trials Results
To avoid misguidance from calls for more routine practice (nontrial) carotid angioplasty/stenting (CAS), we need to distinguish relevant facts and patients’ best interests from all else (distractions). A recent editorial by White and Jaff1 is one publication which illustrates this need particularly well. First, these authors are correct in reminding us that the responsibility of physicians is to provide best patient care, putting aside personal interest. This is inherent in any profession.2 However, misconception, bias, and conflict of interest exist. Therefore, healthcare payment organizations, such as the US Center for Medicare and Medicaid Services are important gatekeepers to facilitate patient access to interventions that are likely to help them, as opposed to all others.
It is also true that CAS and carotid endarterectomy (CEA) result in better outcomes when patients are carefully selected and skilled operators perform the procedures in experienced centers.1 We would add that key indicators (such as 30‐day periprocedural stroke/death rates) must be accurately measured in routine (real‐world) practice, particularly as stroke and death rates here may be unacceptably higher than in trials. 3–5 Therefore, it is most appropriate, as suggested by White and Jaff,1 that coverage for carotid procedures be dependent on facility accreditation and audited measurement of key standards indicators in all practices performing these procedures.
This is a priority issue. White and Jaff1 also correctly state “a major change in evidence based stroke prevention strategies will require clinical trial data.,7,8 meta‐analyses, and routine practice.9–14 Most of these data relate to low/average risk symptomatic patients and demonstrate that, for these patients, even in the best academic centers, CAS is consistently associated with significantly higher rates of stroke or death (during or after the periprocedural period) compared with CEA.
It is incorrect that CREST “failed to show a difference in overall stroke rate between CAS and CEA” as stated by White and Jaff.1 In CREST, for average surgical risk symptomatic patients, the periprocedural stroke and death rates were 6.0% for CAS versus 3.2% for CEA (hazard ratio, 1.89; 95% confidence interval, 1.11–3.21; P=0.02).8
The higher periprocedural risk of stroke or death with CAS is particularly evident in the most senior patients (>68–70 years),13,15,16 those undergoing the procedure <7 days of incident cerebral or retinal ischemic symptoms17 (when CEA has the highest stroke prevention potential),18 those undergoing CAS outside clinical trials,19 and those with certain anatomic features.20 No study has shown that CAS is more effective than CEA in preventing stroke. Further, most analyses show that CAS costs considerably more,21–24 despite calculations derived from CREST results.25 No randomized trial has been adequately powered to compare the procedural and longer term risk of CAS on stroke or death in low/average risk asymptomatic patients. However, in CREST, the direction of effect was toward nearly twice the risk (periprocedural stroke/death rate was 2.5% for CAS versus 1.4% for CEA; hazard ratio, 1.88; 95% confidence interval, 0.79–4.42; P=0.15).8 This was consistent with the significantly higher periprocedural stroke rates seen in CREST CAS‐treated symptomatic patients8 and nontrial CAS‐treated asymptomatic patients.9,26
Meanwhile, medical treatment for asymptomatic carotid disease has improved significantly since past randomized trials of medical treatment alone versus additional CEA.27–32 Medical treatment consists of identification of risk factors for heart and vascular disease and risk reduction using healthy lifestyles and appropriate drugs. Improvement in medical treatment is clear from robust analyses of all published comparable, quality stroke rate calculations (including from, and within, randomized surgical trials) of patients with 50% to 99% asymptomatic carotid stenosis. This knowledge is not, as claimed by White and Jaff,1 derived from short‐cut extrapolation from coronary artery trials. Using the same standardized rate calculations, we are now seeing an average annual rate of ipsilateral stroke of ≈0.5% with medical treatment alone.30,33,34 This is about 3X— lower than that of asymptomatic CREST CAS‐treated patients and about half the rate of asymptomatic CREST CEA‐treated patients.7,9 This low rate with medical treatment is likely to fall further with improvements in efficacy, definition, and implementation.
However, recently published rate calculations indicate that, at most, only ≈2.5% of low/average CEA risk patients with 50% to 99% asymptomatic carotid stenosis will receive a stroke prevention benefit from CEA or CAS during their remaining average 10‐year lifetime if they receive good, current medical treatment (assuming the procedural risk of stroke/death is always zero).35 This indicates that a one‐size‐fits‐all procedural approach for these asymptomatic patients is now unlikely to be beneficial overall. We need to be much more selective. Research is required to determine which asymptomatic subgroups now benefit from carotid procedures in addition to current optimal medical treatment.
We have found no direct information about the influence of current medical treatment in patients with low/average CEA risk symptomatic carotid stenosis. However, improving results for medically treated asymptomatic patients27–32 and procedural trial asymptomatic and symptomatic patients8 indicate that a 6% periprocedural risk of
stroke or
death (the current standard) is now too high.
New randomized and risk stratification studies are required using current optimal medical treatment and procedural methods.36 For example,
improved plaque37 and
thrombus identification38 or
embolic signal detection39 above and below the stenosis
may help better identify carotid plaques responsible for carotid territory ischemic symptoms. Further, the best approach for patients with high surgical risk carotid stenosis remains uncertain because risk of stroke or death has not been measured with any standard of medical treatment or adequate procedural trials. However, some registries show significantly higher risks of stroke/death with CAS compared with CEA in asymptomatic and symptomatic high surgical risk patients.40
Incidence of MI
Calls from other authors for more routine CAS on the grounds of lower periprocedural myocardial infarction (MI) rates compared with CEA are distracting.41 MI is not a measure of stroke prevention efficacy, even though it is an important procedural complication. The inclusion of periprocedural MI with stroke and death in the primary outcome measure in CREST resulted in primary outcome equivalence between CAS and CEA. However, it did not result in efficacy equivalence. In CREST, 1.1% (14/1262) of CAS patients had periprocedural clinical MI (biomarkers plus chest pain/ECG evidence) compared with 2.3% (28/1240) of CEA patients7 (P=0.03). However, periprocedural stroke was nearly twice as common (81/2502; 3.2%)7 as periprocedural clinical MI (42/2502; 1.7%) and, as mentioned above, CAS caused almost twice as many of these strokes as CEA.Further, in CREST, the mortality rate up to 4 years was equally poor for CREST patients with periprocedural stroke (20%),42 periprocedural clinical MI (19%),41 or periprocedural biomarker‐positive only MI (25%).41 Finally, nonfatal stroke was associated with a poorer quality of life at 1 year than nonfatal MI.7 Therefore, MI is a measure of carotid procedural risk (not benefit) and must be considered separately from stroke risk. Moreover, in CREST, CAS‐associated stroke was more troublesome for patients than CEA‐associated MI.
Conclusion
Calls for More Routine Carotid Stenting Are Currently Inappropriate, 3/2013
Carotid artery disease, also called carotid artery stenosis, occurs when the carotid arteries, the main blood vessels that carry oxygenated blood to the brain, become narrowed. The narrowing of the carotid arteries is most commonly related to atherosclerosis (a buildup of plaque, which is a deposit of fatty substances, cholesterol, cellular waste products, calcium, and fibrin in the inner lining of an artery). Atherosclerosis, or “hardening of the arteries,” is a vascular disease (disease of the arteries and veins). Carotid artery disease is similar to coronary artery disease, in which blockages occur in the arteries of the heart, and may cause a heart attack.
Click Image to Enlarge
To better understand how carotid artery disease affects the brain, a basic review of the anatomy of the circulation system of the brain follows.
What are the carotid arteries?
The main supply of blood to the brain is carried by the carotid arteries. The carotid arteries branch off from the aorta (the largest artery in the body) a short distance from the heart, and extend upward through the neck carrying oxygen-rich blood to the brain.
There are four carotid arteries: the right and left internal carotid arteries and the right and left external carotid arteries. One pair (external and internal) is located on each side of the neck. Just as a pulse can be felt in the wrists, a pulse can also be felt on either side of the neck over the carotid arteries.
Click to Enlarge
Why are the carotid arteries important?
Because the carotid arteries deliver blood to the brain, carotid artery disease can have serious implications by reducing the flow of oxygen to the brain. The brain needs a constant supply of oxygen in order to function. Even a brief interruption in blood supply can cause problems. Brain cells begin to die after just a few minutes without blood or oxygen. If the narrowing of the carotid arteries becomes severe enough to block blood flow, or a piece of atherosclerotic plaque breaks off and obstructs blood flow to the brain, a stroke may occur.
What causes carotid artery disease?
Atherosclerosis is the most common cause of carotid artery disease. It is unknown exactly how atherosclerosis begins or what causes it. Atherosclerosis is a slow, progressive, vascular disease that starts as early as childhood. However, the disease has the potential to progress rapidly. It is generally characterized by the accumulation of fatty deposits along the innermost layer of the arteries. If the disease process progresses, plaque formation may take place. Plaque is made up of deposits of smooth muscle cells, fatty substances, cholesterol, calcium, and cellular waste products. This thickening narrows the arteries and can decrease blood flow or completely block the flow of blood to the brain.
Risk factors associated with atherosclerosis include:
Older age
Male
Family history
Race or ethnicity
Genetic factors
Hyperlipidemia (elevated fats in the blood)
Hypertension (high blood pressure)
Smoking
Diabetes
Obesity
Diet high in saturated fat
Lack of exercise
A risk factor is anything that may directly increase or be associated with a person’s chance of developing a disease. It may be an activity, such as smoking, diet, family history, or many other things. Different diseases have different risk factors.
Although these risk factors increase a person’s risk, they do not necessarily cause the disease. Some people with one or more risk factors never develop the disease, while others develop disease and have no known risk factors. Knowing your risk factors to any disease can help to guide you into the appropriate actions, including changing behaviors and being clinically monitored for the disease.
What are the symptoms of carotid artery disease?
Carotid artery disease may be asymptomatic (without symptoms) or symptomatic (with symptoms). Asymptomatic carotid disease is the presence of a significant amount of atherosclerotic buildup without obstructing enough blood flow to cause symptoms. However, a sufficiently tight stenosis will not always cause symptoms. Symptomatic carotid artery disease may result in either a transient ischemic attack (TIA) and/or a stroke (brain attack).
A transient ischemic attack (TIA) is a sudden or temporary loss of blood flow to an area of the brain, usually lasting a few minutes to one hour. Symptoms go away entirely within 24 hours, with complete recovery. Symptoms of a TIA may include, but are not limited to, the following:
Sudden weakness or clumsiness of an arm and/or leg on one side of the body
Sudden paralysis (inability to move) of an arm and/or leg on one side of the body
Loss of coordination or movement
Confusion, decreased ability to concentrate, dizziness, fainting, and/or headache
Numbness or loss of sensation (feeling) in the face
Numbness or loss of sensation in an arm and/or leg
Temporary loss of vision or blurred vision
Inability to speak clearly or slurred speech
TIA may be related to severe narrowing or blockage or from small pieces of an atherosclerotic plaque breaking off, traveling through the bloodstream, and lodging in small blood vessels in the brain. With TIA, there is rarely permanent brain damage.
Call for medical help immediately if you suspect a person is having a TIA, as it may be a warning sign that a stroke is about to occur. Not all strokes, however, are preceded by TIAs.
Stroke is another indicator of carotid artery disease. The symptoms of a stroke are the same as for a TIA. A stroke is loss of blood flow (ischemia) to the brain that continues long enough to cause permanent brain damage. Brain cells begin to die after just a few minutes without oxygen. The area of dead cells in tissues is called an infarct.
The area of the brain that suffered the loss of blood flow will determine what the physical or mental disability may be. This may include impaired ability with movement, speech, thinking and memory, bowel and bladder function, eating, emotional control, and other vital body functions. Recovery from the specific ability affected depends on the size and location of the stroke. A stroke may result in problems, such as weakness in an arm or leg or may cause paralysis, loss of speech, or even death.
The symptoms of carotid artery disease may resemble other medical conditions or problems. Always consult your doctor for a diagnosis.
How is carotid artery disease diagnosed?
In addition to a complete medical history and physical examination, diagnostic procedures for carotid artery disease may include any, or a combination, of the following:
Auscultation (listening to) of carotid arteries. Placement of a stethoscope over the carotid artery to listen for a particular sound called a bruit (pronounced brew-ee). A bruit is an abnormal sound that is produced by blood passing through a narrowed artery. A bruit is generally considered a sign of an atherosclerotic artery; however, an artery may be diseased without producing this sound.
Carotid artery duplex scan. A type of vascular ultrasound study performed to assess the blood flow of the carotid arteries. A carotid artery duplex scan is a noninvasive (the skin is not pierced) procedure. A probe called a transducer sends out ultrasonic sound waves at a frequency too high to be heard. When the transducer (like a microphone) is placed on the carotid arteries at certain locations and angles, the ultrasonic sound waves move through the skin and other body tissues to the blood vessels, where the waves echo off of the blood cells. The transducer picks up the reflected waves and sends them to an amplifier, which makes the ultrasonic sound waves audible. Absence or faintness of these sounds may indicate an obstruction to the blood flow.
Magnetic resonance imaging (MRI). A diagnostic procedure that uses a combination of large magnets, radiofrequencies, and a computer to produce detailed images of organs and structures within the body. To have this test done, you lie inside a big tube while magnets pass around your body. It is very loud. Sometimes it is done with IV contrast injected into your veins and sometimes not.
Magnetic resonance angiography (MRA). A noninvasive diagnostic procedure that uses a combination of magnetic resonance technology (MRI) and intravenous (IV) contrast dye to visualize blood vessels. Contrast dye causes blood vessels to appear opaque on the MRI image, allowing the doctor to visualize the blood vessels being evaluated.
Computed tomography scan (also called a CT or CAT scan). A diagnostic imaging procedure that uses a combination of X-rays and computer technology to produce horizontal, or axial, images (often called slices) of the body. A CT scan shows detailed images of any part of the body, including the bones, muscles, fat, and organs. CT scans are more detailed than general X-rays. Like an MRI, it is sometimes done with IV contrast injected into your veins and sometimes not.
Angiography. An invasive procedure used to assess the degree of blockage or narrowing of the carotid arteries by taking X-ray images while a contrast dye in injected. The contrast dye helps to visualize the shape and flow of blood through the arteries as X-ray images are made.
Treatment for carotid artery disease
Specific treatment for carotid artery disease will be determined by your doctor based on:
Your age, overall health, and medical history
Extent of the disease
Your signs and symptoms
Your tolerance of specific medications, procedures, or therapies
Expectations for the course of the disease
Your opinion or preference
Carotid artery disease (asymptomatic or symptomatic) in which the narrowing of the carotid artery is less than 50 percent is most often treated medically. Asymptomatic disease with less than 70 percent narrowing may also be treated medically, depending on the individual situation.
Medical treatment for carotid artery disease may include:
Modification of risk factors. Risk factors that may be modified include smoking, elevated cholesterol levels, elevated blood glucose levels, lack of exercise, poor dietary habits, and elevated blood pressure.
Medications. Medications that may be used to treat carotid artery disease include:
Antiplatelet medications. Medications used to decrease the ability of platelets in the blood to stick together and cause clots. Aspirin, clopidogrel, and dipyridamole are examples of antiplatelet medications.
Antihyperlipidemics. Medications used to lower lipids (fats) in the blood, particularly cholesterol. Statins are a group of antihyperlipidemic medications, and include simvastatin, atorvastatin, and pravastatin, among others. Studies have shown that certain statins can decrease the thickness of the carotid artery wall and increase the size of the lumen (opening) of the artery.
Antihypertensives. Medications used to lower blood pressure. There are several different groups of medications which act in different ways to lower blood pressure.
In people with narrowing of the carotid artery greater than 50 to 69 percent, a more aggressive treatment may be recommended, particularly in people with symptoms. Surgical treatment decreases the risk for stroke after symptoms such as TIA or minor stroke, especially in people with an occlusion (blockage) of more than 70 percent who are good candidates for surgery.
Surgical treatment of carotid artery disease includes:
Carotid endarterectomy (CEA). Carotid endarterectomy is a procedure used to remove plaque and clots from the carotid arteries, located in the neck. Endarterectomy may help prevent a stroke from occurring in people with symptoms with a carotid artery narrowing of 70 percent of more.
Illustration of Carotid Endarterectomy (Click to Enlarge)
Carotid artery angioplasty with stenting (CAS). Carotid angioplasty with stenting is an option for patients who are high risk for carotid endarterectomy. This is a minimally invasive procedure in which a very small hollow tube, or catheter, is advanced from a blood vessel in the groin to the carotid arteries. Once the catheter is in place, a balloon may be inflated to open the artery and a stent is placed. A stent is a cylinder-like tube made of thin metal-mesh framework used to hold the artery open. Because there is a risk of stroke from bits of plaque breaking off during the procedure, an apparatus, called an embolic protection device, may be used. An embolic protection device is a filter (like a small basket) that is attached on a guidewire to catch any debris that may break off during the procedure.
Carotid Artery Angioplasty with Stenting (CAS) Click to Enlarge
Carotid Artery Disease and Stroke: Prevention and Treatment – John Hopkins
VIEW VIDEO –
Carotid Endarterectomy with Temporary Bypass – A Fifty year old procedure
Docteur Jean VALLA
Chirurgien Cardiovasculaire et Thoracique
AIHR/ACCA – Ancien Chirurgien des Hôpitaux Universitaires.
Membre de la Société de Chirurgie Thoracique et Cardiovasculaire de Langue Française Conventionné
Carotid artery stenosis is the narrowing of the carotid arteries. These are the main arteries in the neck that supply blood to the brain. Carotid artery stenosis, also called carotid artery disease, is a major risk factor for ischemic stroke.The narrowing is usually caused by plaque in a blood vessel. Plaque forms when cholesterol, fat and other substances build up in the inner lining of an artery.Depending on the degree of stenosis and the patient’s overall condition, carotid artery stenosis can usually be treated with surgery. The procedure is called carotid endarterectomy. It removes the plaque that caused the carotid artery to narrow. Carotid endarterectomy has proven to benefit patients with arteries stenosed (narrowed) by 70 percent or more. For people with arteries narrowed less than 50 percent, anti-clotting medicine is usually prescribed to reduce the risk of ischemic stroke.
VIEW VIDEO –
Carotid angioplasty and stenting (CAS) – Mayo Clinic
In carotid angioplasty and stenting, a long hollow tube called a catheter is inserted in the femoral artery in the groin area. The catheter is then maneuvered through the arteries until it reaches the narrowing in the carotid artery in the neck. An umbrella-shaped filter is inserted beyond the narrowing to catch any plaque or debris that may break off during the procedure. Then, a tiny balloon at the end of the catheter is inflated to push the plaque to the side and widen the vessel. A small metal coil called a stent is inserted into the vessel. The stent serves as a scaffold to help prevent the artery from narrowing again.
Contributions of a Vascular Surgeon at Peak Career – Richard Paul Cambria, MD, Chief, Division of Vascular and Endovascular Surgery Co-Director, Thoracic Aortic Center @ MGH
I. Recollection of a visit at Dr. Cambria’s Office @MGH, 2004
The author arrived for a 4PM appointment @ MGH with a referral from NWH for a Carotid artery duplex scan that in 2004 was not performed at NWH. The consultation appointment with Dr. Kwolek CJ, a vascular surgeon trained under Dr. RP Cambria, took place in Dr. Cambria’s Office. Few minutes into the patient Medical History interview, Dr. Kwolek was called for an emergency in the OR and asked me to wait for him till he comes back. I looked around and found myself in a 14’x22′ Room, the Office of Dr. Richard Cambria @ MGH, Chief Vascular Surgery and among the Top ten in the World. Except for the glass entrance door and the wide window to the right of the entrance – 3 1/2 walls from the ceiling to one yard above the floor where completely covered with framed Awards, licenses, renewed licenses, Pictures with graduating Medical Students, Pictures with Faculty, with Patients and in the OR. I waited for Dr. Kwolek’s return for the completion of my Medical History Interview about 30 minutes. I used that time to walk along the walls in Dr. Cambria’s Office and read the framed Exhibits. It was clear to me that this Office will need, one day, in the future, to become a Museum @MGH, for most significant milestones in Vascular Surgery, a branch of Cardiothoracic Surgery. Dr. Kwolek returned and completed the interview, scheduled my Lab appointment and the next appointment to discuss the duplex scan results.
II. Shadowing Dr. Cambria in OR @MGH
Per section IV, below which described the author’s Cardiovascular Clinical Observational Experience, I recorded my Shadowing experience at the OR @MGH, including Dr. Cambria performing a CEA on a 84 year old women under going aorta valve replacement (performed by Dr. Walker) priot to a CEA performed by Dr. Cambria. It was all captivating to watch his double gloved hands performing sutures on a >95% blocked carotid artery prior to incision.
The dexterity and the speed of Dr. Cambria’s fingers’ movement, could only have reminded me of World #1 Harp Player: Nicanor Zabaleta, which I met in person, in the presence of my prominent Harp teacher, on his US Tour in 11/1989. He was awarded the Premio Nacional de Música of Spain in 1982 and six years later, in 1988, he was elected to the Real Academia de Bellas Artes de San Fernando. Dr. Cambria’s and Mr. Zabaleta’s fingers dexterity and eye hand coordination, both are of the rarest endowments in fine motor precision and perfection with Worldly finest outcomes in art, Surgery is Art, the mastering of the Harp is Art, too.
The Author in the OR — Mass General Hospital, Boston
Cardiac Surgery – Operating Room
Supervisor: Dr. J. Walker, Cardiac Surgeon
Experience: Shadowing Open Heart Surgery at MGH
1/24/2005: Carotid Artery endarterectomy operation by Dr. Richard Cambria
1/24/2005: Mitral Valve Replacement by Dr. Jennifer Walker
1/26/2005: Aorta Valve Replacement and Coronary Artery Bypass Grafting by Dr. Jennifer Walker
[Saphenous vein harvested from the leg and Radial vein harvested from the right arm]
III. Dr. Cambria: Selection of Contributions to Scientific Research on Vascular Surgery
The Author covered In Part One, Dr. Cambria’s participation in and contribution to the International, Multispecialty Position Statement on Carotid Stenting, 2013.
In Part Two Section II, I share with the e-Reader watching Dr. Cambria in the Surgical Theater performing CEA
In Part Two Section III, I am carrying with me the heavy weight of my Recollections from a Visit to his Office in 2004, my experience shadowing Dr. Cambria in the OR @MGH on 1/24/2005. Now I am giving back.
I became aware that both events have impacted favorably my 7/2013, Editorial decision, for a forthcoming book on Cardiovascular Disease in 2013. The Editorial decision is two fold:
the selection and representation of a prominent Vascular Surgery Center in the US, @MGH, and
my personal decision to select a Vascular Surgeon at Peak Career – Richard Paul Cambria, MD @MGH.
The decision to focus on Peripheral Vascular Surgery @MGH as described in Dr. Richard P Cambria’s research had yielded one Sub-Chapter (5.5) in Chapter 5
Chapter 5
Invasive Procedures by Surgery versus Catheterization
in Volume Three in a forthcoming three volume Series of e-Books on Cardiovascular Diseases
This very Sub-Chapter, 5.5, represents milestones in Dr. Cambria as a Vascular Surgeon. His eminent profile as a Vascular Surgery Researcher, is now in:
IV. Cardiovascular Clinical Observational Experience – Aviva Lev-Ari, PhD, RN
Brigham and Women’s Hospital, Boston. MA
Cardiac ICU, Coronary Care Unit, Medical Rounds [100 hours] June 2006-November 2006
Brigham and Women’s Hospital, Boston. MA
CDIC – Cardiovascular Diagnostic and Interventional Center
Angiography & Interventional Radiology [100 hours] March 2006-August 2006
Experience shadowing the daily activities of three Physician Assistants
1. attended consultation appointments with patient candidate for procedures: fibroid embolization
2. patient candidate for intra-vertebral cement injection in fractured vertebrae in spinal column, L-9 – Kyphoplasty vertebral augmentation
3. drainage of bile leakage – biliary duct obstruction
4. attended invasive procedures in the Angiography Lab
5. attended 7:30AM department meeting on all cases scheduled for procedures in the Lab for the day
6. discussed procedure outcomes and patient follow ups with PAs
7. Shadowing PAs and Interventional Radiologists performing angiography.
– VENOUS ACCESS PROCEDURES – TUNNELED CATHETER AND PORT PLACEMENT
– DIALYSIS ACCESS MANAGEMENT – ARTERIOVENOUS FISTULA/GRAFT.
ANGIOGRAMS/ANGIOPLASTIES
Mass General Hospital, Boston
Cardiac Catheterization Lab
Supervisor: Dr. Igor Palacios, Director, Cath Lab
Experience Shadowing in the Cath Lab at MGH
1/19/2005: stenting – MI case, mitral valve opening with balloon
The cerebral hyperperfusion syndrome is a very rare complication after revascularization of the carotid artery and accompanied by postoperative or postinterventional hypertension in almost all patients. We report a case of a 77-year-old man who developed a complete aphasia and increased right-sided weakness following endovascular treatment of severe occlusive disease of the left internal carotid artery. We discuss the risk and management of cerebral hyperperfusion syndrome after carotid artery stenting.
Introduction
Neurological complications following carotid artery stenting (CAS) are usually ischemic in nature, due to embolization or occlusion of the carotid artery. However, in a small subset of patients, cerebral hyperperfusion causes postinterventional neurological dysfunction, characterized by ipsilateral headache, focal seizure activity, focal neurological deficit, and ipsilateral intracerebral edema or hemorrhage. A high clinical suspicion and early diagnosis will allow early initiation of therapy and preventing fatal brain swelling or bleeding in patients with peri- and postinterventional cerebral hyperperfusion syndrome (CHS).
Discussion
In 1981, Sundt et al. [1] described a triad of complications that included atypical migrainous phenomena, transient focal seizure activity, and intracerebral hemorrhage after CEA and used the term cerebral hyperperfusion syndrome (CHS). The first report on CHS after CAS was published by Schoser et al. [2]. They described a 59-year-old woman with ipsilateral putaminal hemorrhage that was diagnosed on the 3rd day after CAS of a high-grade stenosis of the left ICA. Outcome in this case was not fatal. The patient recovered with a mild upper limb paresis. McCabe et al. [3] were the first to report the occurrence of fatal ICH soon after CAS. Only a few hours after the procedure, neurological symptoms occurred without any prodromata (severe headache, nausea, and seizures) postulated by Sundt et al. [1] to be an obligate component of CHS. CT of the brain revealed extensive ICH and the patient died 18 days later. Abou-Chebl et al. [4] reported a retrospective single-center study on 450 patients who had been treated with CAS. Three patients (0.67%) developed ICH after the intervention. Further reports on results and complications after CAS have been published [5]. Nearly all reports on CHS after carotid revascularizations in general and CAS in particular have in common patients who had high-grade stenoses in the treated vessel.
CHS following surgical or endovascular treatment of severe carotid occlusive disease is thought to be the result of impaired cerebral autoregulation, hypertension, ischemia-reperfusion injury, oxygen-derived free radicals, baroreceptor-dysfunction, and intraprocedural ischemia [6]. Chronic cerebral hypoperfusion due to critical stenosis leads to production of vasodilatory substances. Autoregulatory failure results in the cerebral arterioles being maximally dilated over a long period of time, with subsequent loss of their ability to constrict when normal perfusion pressure is restored. The degree of microvascular dysautoregulation is proportional to the duration and severity of ischemia determined by the severity of ipsilateral stenosis and poor collateral flow.
Hypertension plays an important role in the development of CHS. In the absence of cerebral autoregulation, cerebral blood flow is directly dependent on the systemic blood pressure. The restoration of normal blood flow to chronically underperfused brain can result in edema, capillary breakthrough, and perivascular and macroscopic hemorrhages aggravated by peri- and postinterventional hypertension [6, 7]. The risk factors for CHS after CAS are summarized in Table 1.
The classic clinical presentation includes ipsilateral headache, seizures or focal neurological deficit, and ipsilateral intracerebral edema or hemorrhage. The diagnosis can be made readily with color Doppler ultrasound of the carotid artery and especially with transcranial Doppler (TCD) of the middle cerebral artery [9]. An increase in peak blood flow velocity of >100% is predictive of postinterventional hyperperfusion. Diffusion weighted MRI or single photon emission computed tomography (SPECT) could also be performed for diagnosis [10]. Angiography normally shows normal findings.
The prognosis of CHS depends on timely recognition of hyperperfusion and adequate treatment of hypertension before cerebral edema or hemorrhage develops. The prognosis following intracerebral bleeding is very poor, with mortality over 50% and significant morbidity of 80% in the survivors [4, 6]. The prognosis of CHS in patients without cerebral edema or hemorrhage is clearly better especially when they are identified and treated early. The most important aspects in preventing and treating this syndrome are early identification, careful monitoring, and control of blood pressure ideally in a high-dependency unit setting. In our special case, early diagnosis of CHS and immediate intensive medical treatment of blood pressure could prevent devastating cerebral edema or hemorrhage following CAS.
Conclusion
CHS, which is characterized by ipsilateral headache, hypertension, seizures, and focal neurological deficits, is a rare but devastating complication following carotid artery stenting. Hypertension is the most important risk factor. The diagnosis can be confirmed quickly by TCD, DWI, or SPECT. Especially peri- or postinterventional TCD monitoring should be available to identify patients with hyperperfusion who may benefit from intensive blood pressure management ideally in a specialized intensive care unit.
Abbreviations
CAS:
Carotid artery stenting
CCA:
Common carotid artery
CEA:
Carotid endarterectomy
CHS:
Cerebral hyperperfusion syndrome
CT:
Computed tomography
CVR:
Cerebrovascular reactivity
DWI:
Diffusion-weighted imaging
ICA:
Internal carotid artery
ICH:
Intracerebral haemorrhage
MRI:
Magnetic resonance imaging
SPECT:
Single photon emission computed tomography
TCD:
Transcranial Doppler.
REFERENCES
T. M. Sundt Jr., F. W. Sharbrough, and D. G. Piepgras, “Correlation of cerebral blood flow and electroencephalographic changes during carotid endarterectomy. With results of surgery and hemodynamics of cerebral ischemia,” Mayo Clinic Proceedings, vol. 56, no. 9, pp. 533–543, 1981.View at Scopus
B. G. H. Schoser, C. Heesen, B. Eckert, and A. Thie, “Cerebral hyperperfusion injury after percutaneous transluminal angioplasty of extracranial arteries,” Journal of Neurology, vol. 244, no. 2, pp. 101–104, 1997. View at Publisher · View at Google Scholar · View at Scopus
D. J. H. McCabe, M. M. Brown, and A. Clifton, “Fatal cerebral reperfusion hemorrhage after carotid stenting,” Stroke, vol. 30, no. 11, pp. 2483–2486, 1999. View at Scopus
A. Abou-Chebl, J. S. Yadav, J. P. Reginelli, C. Bajzer, D. Bhatt, and D. W. Krieger, “Intracranial hemorrhage and hyperperfusion syndrome following carotid artery stenting: risk factors, prevention, and treatment,” Journal of the American College of Cardiology, vol. 43, no. 9, pp. 1596–1601, 2004. View at Publisher · View at Google Scholar · View at Scopus
J.-H. Buhk, L. Cepek, and M. Knauth, “Hyperacute intracerebral hemorrhage complicating carotid stenting should be distinguished from hyperperfusion syndrome,” American Journal of Neuroradiology, vol. 27, no. 7, pp. 1508–1513, 2006. View at Scopus
W. F. Morrish, S. Grahovac, A. Douen et al., “Intracranial hemorrhage after stenting and angioplasty of extracranial carotid stenosis,” American Journal of Neuroradiology, vol. 21, no. 10, pp. 1911–1916, 2000. View at Scopus
R. Gupta, A. Abou-Chebl, C. T. Bajzer, H. C. Schumacher, and J. S. Yadav, “Rate, predictors, and consequences of hemodynamic depression after carotid artery stenting,” Journal of the American College of Cardiology, vol. 47, no. 8, pp. 1538–1543, 2006. View at Publisher · View at Google Scholar · View at Scopus
M. B. Sánchez-Arjona, G. Sanz-Fernández, E. Franco-Macias, and A. Gil-Peralta, “Cerebral hemodynamic changes after carotid angioplasty and stenting,” American Journal of Neuroradiology, vol. 28, pp. 640–644, 2007.
Y. Kaku, S. I. Yoshimura, and J. Kokuzawa, “Factors predictive of cerebral hyperperfusion after carotid angioplasty and stent placement,” American Journal of Neuroradiology, vol. 25, pp. 1403–1408, 2004.
Patient came to her appointment as part of a standard pre-operative evaluation for removal of a uterine myoma. She had a history of stroke with residual slurred speech, making it difficult to understand her. Accordingly, I assumed I would see some carotid stenosis, but her ultrasound showed a stunning 70-99% stenosis in her right internal carotid artery and full occlusion of her left internal carotid artery.
Flow in the common carotid arteries looked fine. The plaque itself in the internal carotid arteries was relatively hypoechoic and not easily visualized in brightness mode, so bidirectional color flow at the proximal internal carotid arteries was surprising. Adding power Doppler allowed me to conclude that there was presence of flow on the right, though minimal, and absolutely no flow in the left internal carotid artery.
Upon completion of the exam, I called the ER and spoke with the doctor, who asked me to bring Rose to the ER. Unfortunately, due to the location of the right internal carotid artery stenosis in the bony canal and total occlusion of the left internal carotid artery, surgery was not an option for clearing out the carotid plaque, but doctors believed she could continue functioning well with collateral vasculature carrying blood to her brain.
Thankfully, the patient passed her other pre-operative tests, consented to her surgery, and underwent general anesthesia with no complications. An 8-cm malignant mass was removed from her uterus and her prognosis is good.
opinion/26redberg.html. Last accessed Jan 8, 2013.
Part Three:
Cleveland Clinic Reports Equivalence between carotid endarterectomy (CEA) and open-heart surgery (OHS) and carotid artery stenting (CAS) followed by coronary artery bypass graft (CABG) surgery or non-CABG cardiac surgery
Stent first, then heart surgery, for patients with severe carotid/coronary disease
Cleveland, OH – With the absence of randomized, controlled clinical trials to address the optimal management of patients with severe carotid and coronary artery disease, a new retrospective study suggests the best tactic is a staged approach that sees the patient undergo carotid artery stenting (CAS) followed by coronary artery bypass graft (CABG) surgery or non-CABG cardiac surgery [1].
Investigators report that a combined approach that includes carotid endarterectomy (CEA) and open-heart surgery (OHS) is equivalent in terms of short-term outcomes with the staged CAS-OHS procedure. Beyond one year, however, the staged CAS-OHS approach resulted in the lowest risk of all-cause mortality, stroke, and MI when compared with a combined CEA-OHS procedure and staged CEA-OHS.
“The surgeons get very worried about doing operations on these patients because they don’t want to do a beautiful job on the bypass only to have the patient have a stroke,” lead investigator Dr Mehdi Shishehbor(Cleveland Clinic, OH) told heartwire.
Shishehbor said that when patients are undergoing open-heart surgery, whether it’s CABG or valve surgery, they are screened for carotid artery disease, given the heightened risk of stroke when undergoing heart surgery. As a result, various teams from neurology, vascular surgery, and interventional cardiology are called to address the safety of the surgery in the setting of severe carotid disease, said Shishehbor.
“These patients are the sickest of the sick in the sense that they have two conditions that are occurring concomitantly,” he said. “These are not patients who just have carotid disease. There are many patients who have moderate or mild carotid disease who undergo open-heart surgery with no problem. These are people with severe disease, those with more than 80% stenosis in one of their carotid arteries or maybe both. They also have severe coronary artery disease. These are people with left-main or three-vessel disease who are destined to undergo bypass.”
The whole point is to prevent stroke
In the study, published this week in the Journal of the American College Cardiology, the investigators reported data on 350 patients who underwent carotid revascularization and cardiac surgery. These included 45 patients who were treated with a staged CEA-OHS approach (OHS performed a median of 14 days after CEA), 110 who were treated with a staged CAS-OHS procedure (OHS performed a median of 47 days after CEA), and 195 patients treated with a combined CEA-OHS procedure. OHS is defined as CABG, CABG plus other cardiac procedures, or non-CABG cardiac surgery (isolated valve or aortic-repair surgery). In total, just 8% of procedures were non-CABG surgeries.
In a propensity-adjusted analysis analyzed by intention-to-treat, the 30-day risk of death, stroke, and MI was similar between the staged CAS-OHS and combined CEA-OHS procedures. The highest risk of the composite end point was observed in patients who underwent staged CEA-OHS.
At one year and beyond (median follow-up was 3.7 years), the staged CAS-OHS patients had the lowest risk of death, stroke, and MI. Compared with staged CEA-OHS, those treated with CAS-OHS had a 67% lower risk of death, stroke, and MI and a 65% lower risk compared with combined CEA-OHS.
Unadjusted comparison of primary/secondary end points
Event
Staged CEA-OHS,n=45 (%)
Combined CEA-OHS,n=195 (%)
Staged CAS-OHS,n=110 (%)
p
Overall 30-d risk post-OHS
31
10
10
0.003
Death
7
5
6
0.75
Stroke
2
7
2
0.11
MI
24
0.5
3
<0.001
Overall composite risk 1 y and beyond
27
39
12
<0.001
Death
38
39
11
<0.001
Stroke
2.2
1.5
0
0.37
MI
0
3.1
2.7
0.5
“In the long term, stenting [followed by OHS] definitely did better than the combined approach,” said Shishehbor. “What’s also important is that with the combined approach, the reason they didn’t do very well is because they had a higher rate of stroke in the perioperative period. . . . Remember the whole point of doing this is to prevent stroke. This is why we feel the combined approach is a little bit inferior to the staged CAS/open-heart-surgery approach. If you have a 7% risk of stroke in the 30-day perioperative period, that doesn’t appear to be the best option for the majority of patients.”
To heartwire, Shishehbor said that while the patients were well matched, the patients undergoing stenting tended to be sicker. For example, they were more likely to have symptomatic carotid stenosis and were more likely to have undergone a previous carotid revascularization. Shishehbor also said that clinical events occurring between the initial carotid artery revascularization procedure and OHS were included in the analysis. These deaths, strokes, and MIs were identified and accounted for in the data.
In an editorial accompanying the study [2], Drs Ehtisham Mahmud and Ryan Reeves (University of California, San Diego) say the work by the Cleveland Clinic group is strengthened by the propensity-adjusted analysis and long follow-up beyond the perioperative period. Most important, they say the study provides clarity for the management of patients with carotid and coronary disease.
“For patients presenting with an acute coronary syndrome requiring urgent coronary revascularization in whom waiting three to four weeks is not safe, combined CEA-OHS is the optimum revascularization strategy, though associated with higher neurological ischemic events,” write Mahmud and Reeves.
“However, for patients with a stable or an accelerating anginal syndrome who can wait three to four weeks to complete dual antiplatelet therapy [DAPT] after carotid stenting, staged CAS followed by OHS leads to superior early and long-term outcomes.”
Since completing the analysis, Shishehbor said there have been discussions with colleagues in vascular surgery, vascular medicine, cardiac surgery, and cardiology to establish the optimum way to treat patients with severe carotid and coronary disease. “The bottom line is that there will never be a randomized, clinical trial in this setting,” he told heartwire. “I hope there would be, but I doubt it. So I think papers like this are critical because we’re doing these procedures to prevent stroke. It’s important that we pick the right procedure for the right patient.”
Confounded by registry requirements
Shishehbor is also concerned about the scrutiny carotid stenting is under from the Centers for Medicare&Medicaid Services(CMS). Currently, the CMS reimburses procedures for asymptomatic patients only if they are included in one of the industry-funded and -maintained registries. He believes the scrutiny has led to a dwindling number of clinicians with the expertise capable of doing the procedure, and this is concerning, since the present analysis shows there are cohorts of asymptomatic patients who would benefit from the treatment.In addition, to be included in a registry, an asymptomatic patient must receive DAPT with aspirin andclopidogrel for four weeks. If the patient does not meet the DAPT requirements, they can’t be included in the registry. However, Shishehbor said, many of these patients have significant coronary disease and can’t wait four weeks. As a result, they are treated with a combined CEA-OHS approach, an approach that is associated with a higher risk of stroke.
Shishehbor reports serving as a speaker and consultant for Abbot Vascular, Medtronic, and Gore but waives all compensation for his work. Mahmud reports trial support from Boston Scientific and Abbott Vascular. In addition,he consults for Cordis andthe Medicines Companyand serves on the speaker‘s bureau for Medtronic. Disclosures for the coauthors are listed in the paper.
Sources
Shishehbor MH, Venkatachalam S, Sun Z, et al. A direct comparison of early and late outcomes with three approaches to carotid revascularization and open heart surgery. J Am Coll Cardiol 2013; available at: http://content.onlinejacc.org.
Mahmud E, Reeves R. Carotid revascularization prior to open heart surgery: The data driven treatment strategy. J Am Coll Cardiol 2013; available at: http://content.onlinejacc.org.
Many radiologists expects that Tomosynthesis will eventually replace conventional mammography due to the fact that it increases the sensitivity of breast cancer detection. This claim is supported by new peer-reviewed publications. In addition, the patient’s experience during Tomosynthesis is less painful due to a lesser pressure that is applied to the breast and while presented with higher in-plane resolution and less imaging artifacts the mean glandular dose of digital breast Tomosynthesis is comparable to that of full field digital mammography. Because it is relatively new, Tomosynthesis is not available at every hospital. As well, the procedure is recognized for reimbursement by public-health schemes.
A good summary of radiologist opinion on Tomosynthesis can be found in the following video:
Recent studies’ results with digital Tomosynthesis are promising. In addition to increase in sensitivity for detection of small cancer lesions researchers claim that this new breast imaging technique will make breast cancers easier to see in dense breast tissue. Here is a paper published on-line by the Lancet just a couple of months ago:
Integration of 3D digital mammography with tomosynthesis for population breast-cancer screening (STORM): a prospective comparison study
Background Digital breast tomosynthesis with 3D images might overcome some of the limitations of conventional 2D mammography for detection of breast cancer. We investigated the effect of integrated 2D and 3D mammography in population breast-cancer screening.
Methods Screening with Tomosynthesis OR standard Mammography (STORM) was a prospective comparative study. We recruited asymptomatic women aged 48 years or older who attended population-based breast-cancer screening through the Trento and Verona screening services (Italy) from August, 2011, to June, 2012. We did screen-reading in two sequential phases—2D only and integrated 2D and 3D mammography—yielding paired data for each screen. Standard double-reading by breast radiologists determined whether to recall the participant based on positive mammography at either screen read. Outcomes were measured from final assessment or excision histology. Primary outcome measures were the number of detected cancers, the number of detected cancers per 1000 screens, the number and proportion of false positive recalls, and incremental cancer detection attributable to integrated 2D and 3D mammography. We compared paired binary data with McNemar’s test.
Findings 7292 women were screened (median age 58 years [IQR 54–63]). We detected 59 breast cancers (including 52 invasive cancers) in 57 women. Both 2D and integrated 2D and 3D screening detected 39 cancers. We detected 20 cancers with integrated 2D and 3D only versus none with 2D screening only (p<0.0001). Cancer detection rates were 5·3 cancers per 1000 screens (95% CI 3.8–7.3) for 2D only, and 8.1 cancers per 1000 screens (6.2–10.4) for integrated 2D and 3D screening. The incremental cancer detection rate attributable to integrated 2D and 3D mammography was 2.7 cancers per 1000 screens (1.7–4.2). 395 screens (5.5%; 95% CI 5.0–6.0) resulted in false positive recalls: 181 at both screen reads, and 141 with 2D only versus 73 with integrated 2D and 3D screening (p<0·0001). We estimated that conditional recall (positive integrated 2D and 3D mammography as a condition to recall) could have reduced false positive recalls by 17.2% (95% CI 13.6–21.3) without missing any of the cancers detected in the study population.
Interpretation Integrated 2D and 3D mammography improves breast-cancer detection and has the potential to reduce false positive recalls. Randomised controlled trials are needed to compare integrated 2D and 3D mammography with 2D mammography for breast cancer screening.
Funding National Breast Cancer Foundation, Australia; National Health and Medical Research Council, Australia; Hologic, USA; Technologic, Italy.
Introduction
Although controversial, mammography screening is the only population-level early detection strategy that has been shown to reduce breast-cancer mortality in randomised trials.1,2 Irrespective of which side of the mammography screening debate one supports,1–3 efforts should be made to investigate methods that enhance the quality of (and hence potential benefit from) mammography screening. A limitation of standard 2D mammography is the superimposition of breast tissue or parenchymal density, which can obscure cancers or make normal structures appear suspicious. This short coming reduces the sensitivity of mammography and increases false-positive screening. Digital breast tomosynthesis with 3D images might help to overcome these limitations. Several reviews4,5 have described the development of breast tomosynthesis technology, in which several low-dose radiographs are used to reconstruct a pseudo-3D image of the breast.4–6
Initial clinical studies of 3D mammography, 6–10 though based on small or selected series, suggest that addition of 3D to 2D mammography could improve cancer detection and reduce the number of false positives. However, previous assessments of breast tomosynthesis might have been constrained by selection biases that distorted the potential effect of 3D mammography; thus, screening trials of integrated 2D and 3D mammography are needed.6
We report the results of a large prospective study (Screening with Tomosynthesis OR standard Mammography [STORM]) of 3D digital mammography. We investigated the effect of screen-reading using both standard 2D and 3D imaging with tomosynthesis compared with screening with standard 2D digital mammography only for population breast-cancer screening.
Methods
Study design and participants
STORM is a prospective population-screening study that compares mammography screen-reading in two sequential phases (figure)—2D only versus integrated 2D and 3D mammography with tomosynthesis—yielding paired results for each screening examination. Women aged 48 years or older who attended population-based screening through the Trento and Verona screening services, Italy, from August, 2011, to June, 2012, were invited to be screened with integrated 2D and 3D mammography. Participants in routine screening mammography (once every 2 years) were asymptomatic women at standard (population) risk for breast cancer. The study was granted institutional ethics approval at each centre, and participants gave written informed consent. Women who opted not to participate in the study received standard 2D mammography. Digital mammography has been used in the Trento breast-screening programme since 2005, and in the Verona programme since 2007; each service monitors outcomes and quality indicators as dictated by European standards, and both have published data for screening performance.11,12
Procedures
All participants had digital mammography using a Selenia Dimensions Unit with integrated 2D and 3D mammography done in the COMBO mode (Hologic, Bedford, MA, USA): this setting takes 2D and 3D images at the same screening examination with a single breast position and compression. Each 2D and 3D image consisted of a bilateral two-view (mediolateral oblique and craniocaudal) mammogram. Screening mammograms were interpreted sequentially by radiologists, first on the basis of standard 2D mammography alone, and then by the same radiologist (on the same day) on the basis of integrated 2D and 3D mammography (figure). Thus, integrated 2D and 3D mammography screening refers to non-independent screen reading based on joint interpretation of 2D and 3D images, and does not refer to analytical combinations. Radiologists had to record whether or not to recall the participant at each screen-reading phase before progressing to the next phase of the sequence. For each screen, data were also collected for breast density (at the 2D screen-read), and the side and quadrant for any recalled abnormality (at each screen-read). All eight radiologists were breast radiologists with a mean of 8 years (range 3–13 years) experience in mammography screening, and had received basic training in integrated 2D and 3D mammography. Several of the radiologists had also used 2D and 3D mammography for patients recalled after positive conventional mammography screening as part of previous studies of tomosynthesis.8,13
Mammograms were interpreted in two independent screen-reads done in parallel, as practiced in most population breast-screening programs in Europe. A screen was considered positive and the woman recalled for further investigations if either screen-reader recorded a positive result at either 2D or integrated 2D and 3D screening (figure). When previous screening mammograms were available, these were shown to the radiologist at the time of screen-reading, as is standard practice. For assessment of breast density, we used Breast Imaging Reporting and Data System (BI-RADS)14 classification, with participants allocated to one of two groups (1–2 [low density] or 3–4 [high density]). Disagreement between readers about breast density was resolved by assessment by a third reader.
Our primary outcomes were the number of cancers detected, the number of cancers detected per 1000 screens, the number and percentage of false positive recalls, and the incremental cancer detection rate attributable to integrated 2D and 3D mammography screening. We compared the number of cancers that were detected only at 2D mammography screen-reading and those that were detected only at 2D and 3D mammography screen-reading; we also did this analysis for false positive recalls. To explore the potential effect of integrated 2D and 3D screening on false-positive recalls, we also estimated how many false-positive recalls would have resulted from using a hypothetical conditional false-positive recall approach; – i.e. positive integrated 2D and 3D mammography as a condition of recall (screening recalled at 2D mammography only would not be recalled). Pre-planned secondary analyses were comparison of outcome measures by age group and breast density.
Outcomes were assessed by excision histology for participants who had surgery, or the complete assessment outcome (including investigative imaging with or without histology from core needle biopsy) for all recalled participants. Because our study focuses on the difference in detection by the two screening methods, some cancers might have been missed by both 2D and integrated 2D and 3D mammography; this possibility could be assessed at future follow-up to identify interval cancers. However, this outcome is not assessed in the present study and does not affect estimates of our primary outcomes – i.e. comparative true or false positive detection for 2D-only versus integrated 2D and 3D mammography.
Statistical analysis
The sample size was chosen to provide 80% power to detect a difference of 20% in cancer detection, assuming a detection probability of 80% for integrated 2D and 3D screening mammography and 60% for 2D only screening, with a two-sided significance threshold of 5%. Based on the method of Lachenbruch15 for estimating sample size for studies that use McNemar’s test for paired binary data, a minimum of 40 cancers were needed. Because most screens in the participating centres were incident (repeat) screening (75%–80%), we used an underlying breast-cancer prevalence of 0·5% to estimate that roughly 7500–8000 screens would be needed to identify 40 cancers in the study population.
We calculated the Wilson CI for the false-positive recall ratio for integrated 2D and 3D screening with conditional recall compared with 2D only screening.16 All of the other analyses were done with SAS/STAT (version 9.2), using exact methods to compute 95 CIs and p-values.
Role of the funding source
The sponsors of the study had no role in study design, data collection, data analysis, data interpretation, or writing of the report. The corresponding author (NH) had full access to all the data in the study and had final responsibility for the decision to submit for publication.
Results
7292 participants with a median age of 58 years (IQR 54–63, range 48–71) were screened between Aug 12, 2011, and June 29, 2012. Roughly 5% of invited women declined integrated 2D and 3D screening and received standard 2D mammography. We present data for 7294 screens because two participants had bilateral cancer (detected with different screen-reading techniques for one participant). We detected 59 breast cancers in 57 participants (52 invasive cancers and seven ductal carcinoma in-situ). Of the invasive cancers, most were invasive ductal (n=37); others were invasive special types (n=7), invasive lobular (n=4), and mixed invasive types (n=4).
Table 1 shows the characteristics of the cancers. Mean tumour size (for the invasive cancers with known exact size) was 13.7 mm (SD 5.8) for cancers detected with both 2D alone and integrated 2D and 3D screening (n=29), and 13.5 mm (SD 6.7) for cancers detected only with integrated 2D and 3D screening (n=13).
Of the 59 cancers, 39 were detected at both 2D and integrated 2D and 3D screening (table 2). 20 cancers were detected with only integrated 2D and 3D screening compared with none detected with only 2D screening (p<0.0001; table 2). 395 screens were false positive (5.5%, 95% CI 5.0–6.0); 181 occurred at both screen-readings, and 141 occurred at 2D screening only compared with 73 at integrated 2D and 3D screening (p<0.0001; table 2). These differences were still significant in sensitivity analyses that excluded the two participants with bilateral cancer (data not shown).
5.3 cancers per 1000 screens (95% CI 3.8–7.3; table 3) were detected with 2D mammography only versus 8.1 cancers per 1000 screens (95% CI 6.2–10.4) with integrated 2D and 3D mammography (p<0.0001). The incremental cancer detection rate attributable to integrated 2D and 3D screening was 2.7 cancers per 1000 screens (95% CI 1.7–4.2), which is 33.9% (95% CI 22.1–47.4) of the cancers detected in the study population. In a sensitivity analysis that excluded the two participants with bilateral cancer the estimated incremental cancer detection rate attributable to integrated 2D and 3D screening was 2.6 cancers per 1000 screens (95% CI 1.4–3.8). The stratified results show that integrated 2D and 3D mammography was associated with an incrementally increased cancer detection rate in both age-groups and density categories (tables 3–5). A minority (16.7%) of breasts were of high density (category 3–4) reducing the power of statistical comparisons in this subgroup (table 5). The incremental cancer detection rate was much the same in low density versus high density groups (2.8 per 1000 vs 2.5 per 1000; p=0.84; table 3).
Overall recall—any recall resulting in true or false positive screens—was 6.2% (95% CI 5.7–6.8), and the false-positive rate for the 7235 screens of participants who did not have breast cancer was 5.5% (5.0–6.0). Table 6 shows the contribution to false-positive recalls from 2D mammography only, integrated 2D and 3D mammography only, and both, and the estimated number of false positives if positive integrated 2D and 3D mammography was a condition for recall (positive 2D only not recalled). Overall, more of the false-positive rate was driven by 2D mammography only than by integrated 2D and 3D, although almost half of the false-positive rate was a result of false positives recalled at both screen-reading phases (table 6). The findings were much the same when stratified by age and breast density (table 6). Had a conditional recall rule been applied, we estimate that the false-positive rate would have been 3.5% (95% CI 3.1–4.0%; table 6) and could have potentially prevented 68 of the 395 false positives (a reduction of 17.2%; 95% CI 13.6–21.3). The ratio between the number of false positives with integrated 2D and 3D screening with conditional recall (n=254) versus 2D only screening (n=322) was 0.79 (95% CI 0.71–0.87).
Discussion
Our study showed that integrated 2D and 3D mammography screening significantly increases detection of breast cancer compared with conventional mammography screening. There was consistent evidence of an incremental improvement in detection from integrated 2D and 3D mammography across age-group and breast density strata, although the analysis by breast density was limited by low number of women with breasts of high density.
One should note that we investigated comparative cancer detection, and not absolute screening sensitivity. By integrating 2D and 3D mammography using the study screen-reading protocol, 1% of false-positive recalls resulted from 2D and 3D screen-reading only (table 6). However, significantly more false positives resulted from 2D only mammography compared with integrated 2D and 3D mammography, both overall and in the stratified analyses. Application of a conditional recall rule would have resulted in a false-positive rate of 3.5% instead of the actual false-positive rate of 5.5%. The estimated false positive recall ratio of 0.79 for integrated 2D and 3D screening with conditional recall compared with 2D only screening suggests that integrated 2D and 3D screening could reduce false recalls by roughly a fifth. Had such a condition been adopted, none of the cancers detected in the study would have been missed because no cancers were detected by 2D mammography only, although this result might be because our design allowed an independent read for 2D only mammography whereas the integrated 2D and 3D read was an interpretation of a combination of 2D and 3D imaging. We do not recommend that such a conditional recall rule be used in breast-cancer screening until our findings are replicated in other mammography screening studies—STORM involved double-reading by experienced breast radiologists, and our results might not apply to other screening settings. Using a test set of 130 mammograms, Wallis and colleagues7 report that adding tomosynthesis to 2D mammography increased the accuracy of inexperienced readers (but not of experienced readers), therefore having experienced radiologists in STORM could have underestimated the effect of integrated 2D and 3D screen-reading.
No other population screening trials of integrated 2D and 3D mammography have reported final results (panel); however, an interim analysis of the Oslo trial17 a large population screening study has shown that integrated 2D and 3D mammography substantially increases detection of breast cancer. The Oslo study investigators screened women with both 2D and 3D mammography, but randomised reading strategies (with vs without 3D mammograms) and adjusted for the different screen-readers,17whereas we used sequential screen-reading to keep the same reader for each examination. Our estimates for comparative cancer detection and for cancer detection rates are consistent with those of the interim analysis of the Oslo study.17 The applied recall methods differed between the Oslo study (which used an arbitration meeting to decide recall) and the STORM study (we recalled based on a decision by either screen-reader), yet both studies show that 3D mammography reduces false-positive recalls when added to standard mammography.
An editorial in The Lancet18 might indeed signal the closing of a chapter of debate about the benefits and harms of screening. We hope that our work might be the beginning of a new chapter for mammography screening: our findings should encourage new assessments of screening using 2D and 3D mammography and should factor several issues related to our study. First, we compared standard 2D mammography with integrated 2D and 3D mammography the 3D mammograms were not interpreted independently of the 2D mammograms therefore 3D mammography only (without the 2D images) might not provide the same results. Our experience with breast tomosynthesis and a review6 of 3D mammography underscore the importance of 2D images in integrated 2D and 3D screen-reading. The 2D images form the basis of the radiologist’s ability to integrate the information from 3D images with that from 2D images. Second, although most screening in STORM was incident screening, the substantial increase in cancer detection rate with integrated 2D and 3D mammography results from the enhanced sensitivity of integrated 2D and 3D screening and is probably also a result of a prevalence effect (ie, the effect of a first screening round with integrated 2D and 3D mammography). We did not assess the effect of repeat (incident) screening with integrated 2D and 3D mammography on cancer detection it might provide a smaller effect on cancer detection rates than what we report. Third, STORM was not designed to measure biological differences between the cancers detected at integrated 2D and 3D screening compared with those detected at both screen-reading phases. Descriptive analyses suggest that, generally, breast cancers detected only at integrated 2D and 3D screening had similar features (eg, histology, pathological tumour size, node status) as those detected at both screen-reading phases. Thus, some of the cancers detected only at 2D and 3D screening might represent early detection (and would be expected to receive screening benefit) whereas some might represent over-detection and a harm from screening, as for conventional screening mam mography.1,19 The absence of consensus about over-diagnosis in breast-cancer screening should not detract from the importance of our study findings to applied screening research and to screening practice; however, our trial was not done to assess the extent to which integrated 2D and 3D mammography might contribute to over-diagnosis.
The average dose of glandular radiation from the many low-dose projections taken during a single acquisition of 3D mammography is roughly the same as that from 2D mammography.6,20–22 Using integrated 2D and 3D entails both a 2D and 3D acquisition in one breast compression, which roughly doubles the radiation dose to the breast. Therefore, integrated 2D and 3D mammography for population screening might only be justifiable if improved outcomes were not defined solely in terms of improved detection. For example, it would be valuable to show that the increased detection with integrated 2D and 3D screening leads to reduced interval cancer rates at follow-up. A limitation of our study might be that data for interval cancers were not available; however, because of the paired design we used, future evaluation of interval cancer rates from our study will only apply to breast cancers that were not identified using 2D only or integrated 2D and 3D screening. We know of two patients from our study who have developed interval cancers (follow-up range 8–16 months). We did not get this information from cancer registries and follow-up was very short, so these data should be interpreted very cautiously, especially because interval cancers would be expected to occur in the second year of the standard 2 year interval between screening rounds. Studies of interval cancer rates after integrated 2D and 3D mammography would need to be randomised controlled trials and have a very large sample size. Additionally, the development of reconstructed 2D images from a 3D mammogram23 provides a timely solution to concerns about radiation by providing both the 2D and 3D images from tomosynthesis, eliminating the need for two acquisitions.
We have shown that integrated 2D and 3D mammography in population breast-cancer screening increases detection of breast cancer and can reduce false-positive recalls depending on the recall strategy. Our results do not warrant an immediate change to breast-screening practice, instead, they show the urgent need for randomised controlled trials of integrated 2D and 3D versus 2D mammography, and for further translational research in breast tomosynthesis. We envisage that future screening trials investigating this issue will include measures of breast cancer detection, and will be designed to assess interval cancer rates as a surrogate endpoint for screening efficacy.
Contributors
SC had the idea for and designed the study, and collected and interpreted data. NH advised on study concepts and methods, analysed and interpreted data, searched the published work, and wrote and revised the report. DB and FC were lead radiologists, recruited participants, collected data, and commented on the draft report. MP, SB, PT, PB, PT, CF, and MV did the screen-reading, collected data, and reviewed the draft report. SM collected data and reviewed the draft report. PM planned the statistical analysis, analysed and interpreted data, and wrote and revised the report.
Conflicts of interest
SC, DB, FC, MP, SB, PT, PB, CF, MV, and SM received assistance from Hologic (Hologic USA; Technologic Italy) in the form of tomosynthesis technology and technical support for the duration of the study, and travel support to attend collaborators’ meetings. NH receives research support from a National Breast Cancer Foundation (NBCF Australia) Practitioner Fellowship, and has received travel support from Hologic to attend a collaborators’ meeting. PM receives research support through Australia’s National Health and Medical Research Council programme grant 633003 to the Screening & Test Evaluation Program.
References
1Independent UK Panel on Breast Cancer Screening. The benefits and harms of breast cancer screening: an independent review. Lancet 2012; 380: 1778–86.
2 Glasziou P, Houssami N. The evidence base for breast cancer screening. Prev Med 2011; 53: 100–102.
3 Autier P, Esserman LJ, Flowers CI, Houssami N. Breast cancer screening: the questions answered. Nat Rev Clin Oncol 2012; 9: 599–605.
4 Baker JA, Lo JY. Breast tomosynthesis: state-of-the-art and review of the literature. Acad Radiol 2011; 18: 1298–310.
5 Helvie MA. Digital mammography imaging: breast tomosynthesis and advanced applications. Radiol Clin North Am 2010; 48: 917–29.
6 Houssami N, Skaane P. Overview of the evidence on digital breast tomosynthesis in breast cancer detection. Breast 2013; 22: 101–08.
7 Wallis MG, Moa E, Zanca F, Leifland K, Danielsson M. Two-view and single-view tomosynthesis versus full-field digital mammography: high-resolution X-ray imaging observer study. Radiology 2012; 262: 788–96.
8 Bernardi D, Ciatto S, Pellegrini M, et al. Prospective study of breast tomosynthesis as a triage to assessment in screening. Breast Cancer Res Treat 2012; 133: 267–71.
9 Michell MJ, Iqbal A, Wasan RK, et al. A comparison of the accuracy of film-screen mammography, full-field digital mammography, and digital breast tomosynthesis. Clin Radiol 2012; 67: 976–81.
10 Skaane P, Gullien R, Bjorndal H, et al. Digital breast tomosynthesis (DBT): initial experience in a clinical setting. Acta Radiol 2012; 53: 524–29.
11 Pellegrini M, Bernardi D, Di MS, et al. Analysis of proportional incidence and review of interval cancer cases observed within the mammography screening programme in Trento province, Italy. Radiol Med 2011; 116: 1217–25.
12 Caumo F, Vecchiato F, Pellegrini M, Vettorazzi M, Ciatto S, Montemezzi S. Analysis of interval cancers observed in an Italian mammography screening programme (2000–2006). Radiol Med 2009; 114: 907–14.
13 Bernardi D, Ciatto S, Pellegrini M, et al. Application of breast tomosynthesis in screening: incremental effect on mammography acquisition and reading time. Br J Radiol 2012; 85: e1174–78.
14 American College of Radiology. ACR BI-RADS: breast imaging reporting and data system, Breast Imaging Atlas. Reston: American College of Radiology, 2003.
15 Lachenbruch PA. On the sample size for studies based on McNemar’s test. Stat Med 1992; 11: 1521–25.
16 Bonett DG, Price RM. Confidence intervals for a ratio of binomial proportions based on paired data. Stat Med 2006; 25: 3039–47.
17 Skaane P, Bandos AI, Gullien R, et al. Comparison of digital mammography alone and digital mammography plus tomosynthesis in a population-based screening program. Radiology 2013; published online Jan 3. http://dx.doi.org/10.1148/ radiol.12121373.
18 The Lancet. The breast cancer screening debate: closing a chapter? Lancet 2012; 380: 1714.
19 Biesheuvel C, Barratt A, Howard K, Houssami N, Irwig L. Effects of study methods and biases on estimates of invasive breast cancer overdetection with mammography screening: a systematic review. Lancet Oncol 2007; 8: 1129–38.
20 Tagliafico A, Astengo D, Cavagnetto F, et al. One-to-one comparison between digital spot compression view and digital breast tomosynthesis. Eur Radiol 2012; 22: 539–44.
21 Tingberg A, Fornvik D, Mattsson S, Svahn T, Timberg P, Zackrisson S. Breast cancer screening with tomosynthesis—initial experiences. Radiat Prot Dosimetry 2011; 147: 180–83.
22 Feng SS, Sechopoulos I. Clinical digital breast tomosynthesis system: dosimetric characterization. Radiology 2012; 263: 35–42.
23 Gur D, Zuley ML, Anello MI, et al. Dose reduction in digital breast tomosynthesis (DBT) screening using synthetically reconstructed projection images: an observer performance study. Acad Radiol 2012; 19: 166–71.
A very good and down-to-earth comment on this article was made by Jules H Sumkin who disclosed that he is an unpaid member of SAB Hologic Inc and have a PI research agreement between University of Pittsburgh and Hologic Inc.
“ The results of the study by Stefano Ciatto and colleagues1 are consistent with recently published prospective,2,3 retrospective,4 and observational5 reports on the same topic. The study1 had limitations, including the fact that the same radiologist interpreted screens sequentially the same day without cross-balancing which examination was read first. Also, the false-negative findings for integrated 2D and 3D mammography, and therefore absolute benefit from the procedure, could not be adequately assessed because cases recalled by 2D mammography alone (141 cases) did not result in a single detection of an additional cancer while the recalls from the integrated 2D and 3D mammography alone (73 cases) resulted in the detection of 20 additional cancers. Nevertheless, the results are in strong agreement with other studies reporting of substantial performance improvements when the screening is done with integrated 2D and 3D mammography.
I disagree with the conclusion of the study with regards to the urgent need for randomised clinical trials of integrated 2D and 3D versus 2D mammography. First, to assess differences in mortality as a result of an imaging-based diagnostic method, a randomised trial will require several repeated screens by the same method in each study group, and the strong results from all studies to date will probably result in substantial crossover and self-selection biases over time. Second, because of the high survival rate (or low mortality rate) of breast cancer, the study will require long follow-up times of at least 10 years. In a rapidly changing environment in terms of improvements in screening technologies and therapeutic interventions, the avoidance of biases is likely to be very difficult, if not impossible. The use of the number of interval cancers and possible shifts in stage at detection, while appropriately accounting for confounders, would be almost as daunting a task. Third, the imaging detection of cancer is only the first step in many management decisions and interventions that can affect outcome. The appropriate control of biases related to patient management is highly unlikely. The arguments above, in addition to the existing reports to date that show substantial improvements in cancer detection, particularly with the detection of invasive cancers, with a simultaneous reduction in recall rates, support the argument that a randomised trial is neither necessary nor warranted. The current technology might be obsolete by the time results of an appropriately done and analysed randomised trial is made public.”
In order to better link the information given by “scientific” papers to the context of daily patients’ reality I suggest to spend some time reviewing few of the videos in the below links:
The following group of videos is featured on a website by Siemens. Nevertheless, the presenting radiologists are leading practitioners who affects thousands of lives every year – What the experts say about tomosynthesis. – click on ECR 2013
Breast Tomosynthesis in Practice – part of a commercial ad of the Washington Radiology Associates featured on the website of Diagnostic Imaging. As well, affects thousands of lives in the Washington area every year.
The pivotal questions yet to be answered are:
What should be done in order to translate increase in sensitivity and early detection into decrease in mortality?
What is the price of such increase in sensitivity in terms of quality of life and health-care costs and is it worth-while to pay?
An article that summarises positively the experience of introducing Tomosynthesis into routine screening practice was recently published on AJR:
Stephen L. Rose1, Andra L. Tidwell1, Louis J. Bujnoch1, Anne C. Kushwaha1, Amy S. Nordmann1 and Russell Sexton, Jr.1
Affiliation: 1 All authors: TOPS Comprehensive Breast Center, 17030 Red Oak Dr, Houston, TX 77090.
Citation: American Journal of Roentgenology. 2013;200:1401-1408
ABSTRACT :
OBJECTIVE. Digital mammography combined with tomosynthesis is gaining clinical acceptance, but data are limited that show its impact in the clinical environment. We assessed the changes in performance measures, if any, after the introduction of tomosynthesis systems into our clinical practice.
MATERIALS AND METHODS. In this observational study, we used verified practice- and outcome-related databases to compute and compare recall rates, biopsy rates, cancer detection rates, and positive predictive values for six radiologists who interpreted screening mammography studies without (n = 13,856) and with (n = 9499) the use of tomosynthesis. Two-sided analyses (significance declared at p < 0.05) accounting for reader variability, age of participants, and whether the examination in question was a baseline were performed.
RESULTS. For the group as a whole, the introduction and routine use of tomosynthesis resulted in significant observed changes in recall rates from 8.7% to 5.5% (p < 0.001), nonsignificant changes in biopsy rates from 15.2 to 13.5 per 1000 screenings (p = 0.59), and cancer detection rates from 4.0 to 5.4 per 1000 screenings (p = 0.18). The invasive cancer detection rate increased from 2.8 to 4.3 per 1000 screening examinations (p = 0.07). The positive predictive value for recalls increased from 4.7% to 10.1% (p < 0.001).
CONCLUSION. The introduction of breast tomosynthesis into our practice was associated with a significant reduction in recall rates and a simultaneous increase in breast cancer detection rates.
Here are the facts in tables and pictures from this article
Other articles related to the management of breast cancer were published on this Open Access Online Scientific Journal:
2013 ACCF/AHA Guideline for the Management of Heart FailureA Report of the American College of Cardiology Foundation/American Heart Association Task Force on Practice Guidelines
Clyde W. Yancy, MD, MSc, FACC, FAHA; Mariell Jessup, MD, FACC, FAHA; Biykem Bozkurt, MD, PhD, FACC, FAHA; Javed Butler, MBBS, FACC, FAHA; Donald E. Casey, MD, MPH, MBA, FACP, FAHA; Mark H. Drazner, MD, MSc, FACC, FAHA; Gregg C. Fonarow, MD, FACC, FAHA; Stephen A. Geraci, MD, FACC, FAHA, FCCP; Tamara Horwich, MD, FACC; James L. Januzzi, MD, FACC; Maryl R. Johnson, MD, FACC, FAHA; Edward K. Kasper, MD, FACC, FAHA; Wayne C. Levy, MD, FACC; Frederick A. Masoudi, MD, MSPH, FACC, FAHA; Patrick E. McBride, MD, MPH, FACC; John J.V. McMurray, MD, FACC; Judith E. Mitchell, MD, FACC, FAHA; Pamela N. Peterson, MD, MSPH, FACC, FAHA; Barbara Riegel, DNSc, RN, FAHA; Flora Sam, MD, FACC, FAHA; Lynne W. Stevenson, MD, FACC; W.H. Wilson Tang, MD, FACC; Emily J. Tsai, MD, FACC; Bruce L. Wilkoff, MD, FACC, FHRS
We present below four National institutions with pubic mandate to promote all Healthcare aspects of Cardiovascular Diseases.
A. 2020 Vision of the Heart Failure Society of America (HFSA)
Special Communication: The Heart Failure Society of America in 2020: A Vision for the Future
Journal of Cardiac Failure Vol. 18 No. 2 2012 written by BARRY H. GREENBERG, MD,1,3 INDER S. ANAND, MD, PhD,2 JOHN C. BURNETT JR, MD,2,3 JOHN CHIN, MD,2,3 KATHLEEN A. DRACUP, RN, DNSc,3 ARTHUR M. FELDMAN, MD, PhD,3 THOMAS FORCE, MD,2,3 GARY S. FRANCIS, MD,3 STEVEN R. HOUSER, PhD,2 SHARON A. HUNT, MD,2 MARVIN A. KONSTAM, MD,3 JOANN LINDENFELD, MD,2,3 DOUGLAS L. MANN, MD,2,3 MANDEEP R. MEHRA, MD,2,3 SARA C. PAUL, RN, DNP, FNP,2,3 MARIANN R. PIANO, RN, PhD,2 HEATHER J. ROSS, MD,2 HANI N. SABBAH, PhD,2 RANDALL C. STARLING, MD, MPH,2 JAMES E. UDELSON, MD,2 CLYDE W. YANCY, MD, MSc,3 MICHAEL R. ZILE, MD,2 AND BARRY M. MASSIE, MD2,3
From the 1Chair, ad hoc Committee for Strategic Development, Heart Failure Society of America; 2Member of Executive Council, Heart Failure Society of America and 3Member, ad hoc Committee for Strategic Development, Heart Failure Society of America.
They write:
The preceding 2 decades had been marked by unprecedented insights into the underlying pathophysiology of cardiac dysfunction that were paralleled by therapeutic advances that, for the first time, were shown to clearly improve outcomes in heart failure patients. At the same time, heart failure prevalence was rapidly increasing throughout the world because of the aging of the population, improved survival of patients with myocardial infarction and other cardiac conditions, and inadequate treatment of common risk factors such as hypertension.
More recently the Heart Failure Society successfully promoted establishment of Advanced Heart Failure and Transplant Cardiology as an American Board of Internal Medicine recognized secondary subspecialty of cardiology developed a board review course to help physicians prepare for the certification examination for the new subspecialty and created a national heart failure review course.
The Society has Advocacy goals, membership goals – to increase by 10% per year for 3 years from all disciplines of Heart Failure.
Education Goals:
The Heart Failure Society of America will be recognized for its innovative approaches to educating and content dissemination on heart failure targeting
healthcare professionals and patients
Grow and enhance the annual meeting through innovative approaches
Continue board review course
Increase web-based programs for patients and health care providers
Enhance the website as a portal for information dissemination for health care professionals and patients
Grow and enhance the relevance and value of the Journal of Cardiac Failure
Conceptual analysis of projection done by the AHA regarding the increase in the Cost of Care for the the American Patient in Heart Failure were developed in the following two articles:
National Heart, Lung, And Blood Institute Working Group identified the most urgent knowledge gaps in Heart Transplantation Research. These gaps require to address the following 4 specific research directions:
enhanced phenotypic characterization of the pre-transplant population
donor-recipient optimization strategies
individualized immunosuppression therapy, and
investigations of immune and non-immune factors affecting late cardiac allograft outcomes.
D. Donor-Recipient Optimization Strategies – 33,640 Cases in the United Network for Organ Sharing database – Organ Donor’s Age is BEST predictor for survival after Heart Transplant
IF the donor age is in the 0- to 19-year-old group the median survival of 11.4 years follows the Heart Transplant.
The effect of ischemic time on survival after heart transplantation varies by donor age: An analysis of the United Network for Organ Sharing database
The Journal of Thoracic and Cardiovascular Surgery ● February 2007
Mark J. Russo, MD, MS,a,b Jonathan M. Chen, MD,a Robert A. Sorabella, BA,a Timothy P. Martens, MD,a
Mauricio Garrido, MD,a Ryan R. Davies, MD,a Isaac George, MD,a Faisal H. Cheema, MD,a Ralph S. Mosca, MD,a Seema Mital, MD,c Deborah D. Ascheim, MD,b,d Michael Argenziano, MD,a Allan S. Stewart, MD,a Mehmet C. Oz, MD,a and Yoshifumi Naka, MD, PhDa
Objectives:
(1) To examine the interaction of donor age with ischemic time and their effect on survival and
(2) to define ranges of ischemic time associated with differences in survival.
Methods: The United Network for Organ Sharing provided de-identified patientlevel data. The study population included 33,640 recipients undergoing heart transplantation between October 1, 1987, and December 31, 2004. Recipients were divided by donor age into terciles: 0 to 19 years (n 10,814; 32.1%), 20 to 33 years (11,410, 33.9%), and 34 years or more (11,416, 33.9%). Kaplan-Meier survival functions and Cox regression were used for time-to-event analysis. Receiver operating characteristic curves and stratum-specific likelihood ratios were generated to compare 5-year survival at various thresholds for ischemic time.
Results: In univariate Cox proportional hazards regression, the effect of ischemic time on survival varied by donor age tercile: 0 to 19 years (P .141), 20 to 33 years (P .001), and 34 years or more (P .001). These relationships persisted in multivariable regression. Threshold analysis generated a single stratum (0.37-12.00 hours) in the 0- to 19-year-old group with a median survival of 11.4 years. However, in the 20- to 33-year-old-group, 3 strata were generated: 0.00 to 3.49 hours (limited), 3.50 to 6.24 hours (prolonged), and 6.25 hours or more (extended), with median survivals of 10.6, 9.9, and 7.3 years, respectively. Likewise, 3 strata were generated in the group aged 34 years or more: 0.00 to 3.49 (limited), 3.50 to 5.49 (prolonged), and 5.50 or more (extended), with median survivals of 9.1, 8.5, and 6.3 years, respectively.
Conclusions: The effect of ischemic time on survival after heart transplantation is dependent on donor age, with greater tolerance for prolonged ischemic times among grafts from younger donors. Both donor age and anticipated ischemic time must be considered when assessing a potential donor.
Procedures Outcomes of Heart Transplant (HT) Indication for Heart Failure (HF)
Center for Heart Failure @Cleveland Clinic, and
Transplant Center @Mayo Clinic
Center for Heart Failure @Cleveland Clinic: Institution Profile
Heart failure (sometimes called congestive heart failure or ventricular dysfunction) means your heart muscle is not functioning as well as it should. Either the left ventricle (lower chamber of the heart) is not contracting with enough force (systolic heart failure), or the ventricles are stiff and do not relax and fill properly (diastolic heart failure). The treatment of heart failure requires a specialized multidisciplinary approach to manage the overall patient care plan.
The George M and Linda H Kaufman Center for Heart Failure is one of the premier facilities in the United States for the care of people with heart failure.
The Kaufman Center Heart Failure Intensive Care was the recipient of the Beacon Award of Excellence for continuing improvements in providing the highest quality of care for patients. With over 6,000 ICUs in the Unites States, the Center joins a distinguished group of just 300 to receive this honor that recognizes the highest level of standards in patient safety and quality in acute and critical care.
In 2011, Cleveland Clinic received the American Heart Association’s Get With The Guidelines Heart Failure GOLD Plus Certification for improving the quality of care for heart failure patients. Gold Plus distinction recognizes hospitals for their success in using Get With The Guidelines treatment interventions. This quality improvement program provides tools that follow proven, evidence-based guidelines and procedures in caring for heart failure patients to prevent future hospitalizations.
The Kaufman Center for Heart Failure Team brings together clinicians that specialize in cardiomyopathies and ischemic heart failure. The team includes physicians and nurses from Cardiovascular Medicine, Cardiothoracic Surgery, Radiology, Infectious Disease, Immunology, Pathology, Pharmacy, Biothetics and Social Work with expertise in diagnostic testing, medical and lifestyle management, surgical procedures, and psychosocial support for patients with:
Patients at Cleveland Clinic Kaufman Center for Heart Failure have available to them the full array of diagnostic testing, treatments and specialized programs.
Outcomes of Heart Failure and Heart Transplant @Cleveland Clinic
1,570 Number of heart transplants performed at Cleveland Clinic since inception of the Cardiac Transplant Program in 1984.
The survival rates among patients who have heart transplants at Cleveland Clinic exceeds the expected rates. Of the 150 transplant centers in the United States, Cleveland Clinic is one of only three that had better-than-expected one-year survival rates in 2011.
Ventricular Assist Device Volume 2007 – 2011
2007 – N = 23
2008 – N = 48
2009 – N = 76
2010 – N = 51
2011 – N = 56
Mechanical circulatory support (MCS) devices are used in patients with heart failure to preserve heart function until transplantation (bridge-to-transplant) or as a final treatment option (destination therapy). Cleveland Clinic has more than 20 years of experience with MCS devices for both types of therapy.
LVAD In-Hospital Mortality 2007 – 2011
Cleveland Clinic continues to make improvements to reduce mortality rates among patients who are placed on mechanical circulatory support. The mortality rate among patients who have a left ventricular assist device (LVAD) has been drastically reduced over the past five years.5% in 2011
VAD Mortality 2011
The mortality rate among Cleveland Clinic patients placed on ventricular assist devices (VADs) was much lower than expected in 2011. Observed 10%, Expected 17.5%
Heart Failure – National Hospital Quality Measures
This composite metric, based on four heart failure hospital quality process measures developed by the Centers for Medicare and Medicaid Services (CMS), shows the percentage of patients who received all the recommended care for which they were eligible. Cleveland Clinic has set a target of UHC’s 90th percentile.
Cleveland Clinic, 2010 (N = 1,194) 93.9%
Cleveland Clinic, 2011 (N = 1,163) 96.9%
UHC Top Decile, 2011 99.2%
SOURCE
University HealthSystem Consortium (UHC) Comparative Database, January through November 2011 discharges.
The Centers for Medicare and Medicaid Services (CMS) calculates two heart failure outcome measures: all-cause mortality and all-cause readmission rates, each based on Medicare claims and enrollment information. Cleveland Clinic’s performance appears below.
Heart Failure All-Cause 30-Day Mortality (N = 762) July 2008 – June 2011
Cleveland Clinic 9.2%
National Average 11.6%
Heart Failure All-Cause 30-Day Readmission (N = 1,029) July 2008 – June 2011
Cleveland Clinic 27.3%
National Average 24.7%
SOURCE:
hospitalcompare.hhs.gov
Cleveland Clinic’s heart failure risk-adjusted 30-day mortality rate is below the national average; the difference is statistically significant. Our heart failure risk-adjusted readmission rate is higher than the national average; that difference is also statistically significant. To further reduce this rate, a multidisciplinary team was tasked with improving transitions from hospital to home or post-acute care facility. Specific initiatives have been implemented in each of these focus areas: communication, education and follow-up.
In 2011, 51% of lung transplant patients were from outside the state of Ohio.
Cleveland Clinic surgeons transplanted 111 lungs in 2011. Our Lung and Heart-Lung Transplant
Program is the leader in Ohio and among the best programs in the country.
July 2010 – June 2011
160 Performed in 2009
Liver-Lung
Heart-Lung
Double Lung
Single Lung
53.5% Idiopathic
Primary Disease of Lung Transplant Recipients (N = 101)
Source: Scientific Registry of Transplant Recipients. March 2011. Ohio, Lung Centers, Cleveland Clinic. Table 7
Cleveland Clinic surgeons transplanted 111 lungs in 2011. Our Lung and Heart-Lung Transplant Program is the leader in Ohio and among the best programs in the country.
Transplant Center @Mayo Clinic: Heart Transplant Procedures Outcomes
Mayo Clinic History
Dr. W.W. Mayo
Drs. William (left) and Charles Mayo
Mayo Clinic developed gradually from the medical practice of a pioneer doctor, Dr. William Worrall Mayo, who settled in Rochester, Minn., in 1863. His dedication to medicine became a family tradition when his sons, Drs. William James Mayo and Charles Horace Mayo, joined his practice in 1883 and 1888, respectively.
From the beginning, innovation was their standard and they shared a pioneering zeal for medicine. As the demand for their services increased, they asked other doctors and basic science researchers to join them in the world’s first private integrated group practice.
Although the Mayo doctors were initially viewed as unconventional for practicing medicine through this teamwork approach, the benefits of a private group practice were undeniable.
As the success of their method of practice became evident, so did its acceptance. Patients discovered the advantages to a “pooled resource” of knowledge and skills among doctors. In fact, the group practice concept that the Mayo family originated has influenced the structure and function of medical practice throughout the world.
Along with its recognition as a model for integrated group practice, “the Mayos’ Clinic” developed a reputation for excellence in individual patient care. Doctors and students came from around the world to learn new techniques from the Mayo doctors, and patients came from around the world for diagnosis and treatment. What attracted them was not only technologically advanced medicine, but also the caring attitude of the doctors.
Through the years, Mayo Clinic has nurtured and developed its founders’ style of working together as a team. Shared responsibility and consensus still provide the framework for decision making at Mayo.
That teamwork in medicine is carried out today by more than 55,000 doctors, nurses, scientists, students and allied health staff at Mayo Clinic locations in the Midwest, Arizona and Florida.
Alternative Solutions to Treatment of Heart Failure
Mayo Clinic, with transplant services in Arizona, Florida and Minnesota, performs more transplants than any other medical center in the world. Mayo Clinic has pre-eminent adult and pediatric transplant programs, offering cardiac, liver, kidney, pancreas and bone marrow transplant services. Since performing the first clinical transplant in 1963, Mayo’s efforts to continually improve and expand organ transplantation have placed Mayo at the leading edge of clinical and basic transplant research worldwide. Research activities in the Transplant Center at Mayo Clinic have contributed significantly to the current successful outcomes of organ transplantation.
People who survive a heart attack face the greatest risk of dying from sudden cardiac death (SCD) during the first month after leaving the hospital, according to a long-term community study by Mayo Clinic researchers of nearly 3,000 heart attack survivors.
Sudden cardiac death can happen when the hearts electrical system malfunctions; if treatment — cardiopulmonary resuscitation and defibrillation — does not happen fast, a person dies.
After that first month, the risk of sudden cardiac death drops significantly — but rises again if a person experiences signs of heart failure. The research results appear in the Nov. 5 edition of Journal of the American Medical Association.
Veronique Roger, M.D., a Mayo Clinic cardiologist provides an overview of the study and it’s findings.
For more information on heart attacks, click on the following link:http://www.mayoclinic.org/heart-attack/
VIEW VIDEOon Mayo Clinic Regenerative Medicine Consult Service – Stem Cell Transplantation post MI
In a proof-of-concept study, Mayo Clinic investigators have demonstrated that induced pluripotent stem (iPS) cells can be used to treat heart disease. iPS cells are stem cells converted from adult cells. In this study, the researchers reprogrammed ordinary fibroblasts, cells that contribute to scars such as those resulting from a heart attack, converting them into stem cells that fix heart damage caused by infarction. The findings appear in the current online issue of the journal Circulation.
Timothy Nelson, M.D., Ph.D., first author on the Mayo Clinic study, talks about the study and it’s findings.
Heart Transplant: Volumes and success measures Transplant Center@ Mayo Clinic
Mayo Clinic doctors’ experience and integrated team approach results in transplant outcomes that compare favorably with national averages. Teams work with transplant recipients before, during and after surgery to ensure the greatest likelihood of superior results.
Volumes and statistics are maintained separately for the three Mayo Clinic locations. Taken together or separately, transplant recipients at Mayo Clinic enjoy excellent results.
Volumes
Arizona
More than 100 heart transplants have been completed since the program began in 2005.
Florida
Surgeons at Mayo Clinic in Florida have performed more than 167 heart transplants and eight heart-lung transplants since the program began in 2001. Mayo surgeons have performed combined transplants, such as heart-kidney and heart-lung-liver transplants.
Minnesota
Mayo Clinic’s outcomes for heart transplantation compare favorably with national norms. Doctors at Mayo Clinic in Minnesota have transplanted more than 450 adult and pediatric patients, including both isolated heart transplants and combined transplants such as heart-liver, heart-kidney and others.
The Center for Heart Failure @Cleveland Clinic’s, and the Transplant Center @Mayo Clinic’s Institutions Profiles, Procedures Outcomes and Selection of their Research are now in:
Article ID #65: Becoming a Cardiothoracic Surgeon: An Emerging Profile in the Surgery Theater and through Scientific Publications. Published on 7/8/2013
WordCloud Image Produced by Adam Tubman
Two components of an Emerging Profile of a Young Cardiothoracic Surgeon were researched by the Author for the case of Dr. Isaac George, Assistant Professor of Surgery, Division of Cardiothoracic Surgery, Department of Surgery, New York Presbyterian Hospital/Columbia University Medical Center , New York, NY.
The two components being:
1. the Cardiothoracic Surgery Theater
2. the Scientific Publications
I noted with interest Dr. George’s second publication, to be about a very well known surgeon in the US and Europe, John Benjamin Murphy. written by Dr. George and two other colleagues, George I, Hardy MA, Widmann WD. published in Curr Surg. 2004 Sep-Oct;61(5):439-41.
I assume that Dr. Murphy’s contributions to Thoracic surgery were of interest to Dr. George to inspire him to write on the subject and elect that Specialty in Surgery.
Murphy was first in the U.S. to induce (1898) artificial immobilization and collapse of the lung in treatment of pulmonary tuberculosis. He was a pioneer in the use of bone grafting and made contributions to the understanding and management of ankylosis as well as independently proposing artificial pneumothorax to manage unilateral lung disease in tuberculosis.
«It is the purpose of every man’s life to do something worthy of the recognition and appreciation of his fellow men. . . . By their superior intellectual qualifications, their fidelity to purpose and above all their indefatigable labour the few become leaders.»
SOURCEWhonamedit? A dictionary of medical eponyms, John Benjamin Murphy
I came across Dr. Isaac George’s name while researching clinical indications for Inhaled Nitric Oxide in June 2013, upon the recent publication of Leaders in Pharmaceutical Business Intelligence FIRST e-Book on Amazon (Biomed e-Books) [Kindle Edition]
Being myself in Analytics and quantitative model design, 1976-2004, I found of particular interest the range of quantitative methodologies used in the following article by Isaac George, assuming that his days at MIT, came very handy in 2006:
George, Isaac, Xydas, Steve, Topkara, Veli K., Ferdinando, Corrina, Barnwell, Eileen C., Gableman, Larissa, Sladen, Robert N., Naka, Yoshifumi, Oz, Mehmet C. Clinical Indication for Use and Outcomes After Inhaled Nitric Oxide Therapy Ann Thorac Surg 2006 82: 2161-2169
As a result of studying this article, I became aware that it has impacted favorably my 6/2013, Editorial decision, for a forthcoming book on Cardiovascular Disease in 2013. The Editorial decision regarding the selection and representation of prominent Cardiothoracic Surgery Theater in the US, and my personal decision to select a Young Cardiothoracic Surgeon
Dr. Isaac George, Assistant Professor of Surgery, Division of Cardiothoracic Surgery, Department of Surgery, New York Presbyterian Hospital/Columbia University Medical Center, New York, NY
Education Profile and Medical Training of a Cardiac Surgeon
NewYork-Presbyterian Hospital/Columbia University Medical Center, New York, NY
2012-present
Assistant Professor of Surgery
Division of Cardiothoracic Surgery, Department of Surgery, New York Presbyterian Hospital/Columbia University Medical Center , New York, NY
Clinical Specialties
Adult aortic and mitral valve surgery
Transcatheter aortic and mitral valve implantation
Hybrid coronary artery bypass surgery
Complex aortic surgery
Complex valvular surgery
Heart failure and transplant surgery
Reoperative cardiac surgery
Thoracic aortic endograft implantation
1. Regulation of myostatin signaling in human cardiomyopathy
2. TGFB regulation in non-syndromic aortic aneurysm formation
3. Valve interstitial cell activation mechanisms after surgical and transcatheter valve replacement
4. Clinical outcomes after valve and hybrid surgery
Education and Training
2011-2012
Interventional Cardiology/Hybrid Cardiac Surgery Fellowship
New York Presbyterian Hospital – Columbia University Medical Center, New York, NY
2011
Ventricular Assist Device/Cardiac Transplant Fellowship, Minimally Invasive, Cardiac Surgery
New York Presbyterian Hospital – Columbia University Medical Center, New York, NY
2009-2011
Fellow, Cardiothoracic Surgery
New York Presbyterian Hospital – Columbia University Medical Center, New York, NY
2008-2009
Post-Doctoral Clinical Fellow, Cardiothoracic Surgery
New York Presbyterian Hospital – Columbia University Medical Center, New York, NY
2006-2008
Resident, General Surgery
New York Presbyterian Hospital – Columbia University Medical Center, New York, NY
2004-2006
Research Fellow, Cardiothoracic Surgery
New York Presbyterian Hospital – Columbia University Medical Center, New York, NY
2002-2004
Resident, General Surgery
New York Presbyterian Hospital – Columbia University Medical Center, New York, NY
2001-2002
Internship, General Surgery
New York Presbyterian Hospital – Columbia University Medical Center, New York, NY
1997-2001
MD, Medicine
Duke University School of Medicine, Durham, NC
1993-1997
BS, Mechanical Engineering
Massachusetts Institute of Technology, Cambridge, MA
Board Certifications
American Board of Thoracic Surgery, 2012-
American Board of Surgery, 2008-
Certification, Pediatric Advanced Life Support, 2008-
Certification, Advanced Trauma Life Support, 2006-
MD, State of New York, 2005-
Certification, Advanced Cardiac Life Support/Basic Life Support, 2001-
United States Medical Licensing Examination Step 3, 2004
United States Medical Licensing Examination Step 2, 2001
United States Medical Licensing Examination Step 1, 2000
Professional Honors
2008 Blakemore Prize – Best Resident Research Award, Columbia University College of Physicians and Surgeons
2007 Blakemore Award – Best Resident Research Award, Columbia University College of Physicians and Surgeons
2006 Blakemore Award – Best Resident Research Award, Columbia University College of Physicians and Surgeons
2004 New Era Cardiac Surgery Conference Scholarship
1995 Pi Tau Sigma, Mechanical Engineering Honor Society
1993 Duke University Comprehensive Cancer Center Fellowship
The decision to focus on Cardiothoracic Surgery @Presbeterian as described in Dr. Isaac George’s research had yielded one Sub-Chapter (4.1) in Chapter 4
Cardiac Surgery, Cardiothoracic Surgical Procedures and Percutaneous Coronary Intervention (PCI)/Coronary Angioplasty – Heart and Cardiovascular Medical Devices in Use in Operating Rooms and in Catheterization Labs in the US
in Volume Three in a forthcoming three volume Series of e-Books on Cardiovascular Diseases
This very Sub-Chapter represents milestones in Dr. Isaac George – Becoming a Cardiothoracic Surgeon: An Emerging Profile through Scientific Publications, This profile is now in:
VIEW VIDEOon Mitral Valve Repair and Replacement – Dr. Karl H. Krieger
Dr. Karl H. Krieger, the Vice Chairman of the Department of Cardiothoracic Surgery at NewYork-Presbyterian Hospital/Weill Cornell Medical Center in New York City, discusses treatment for Mitral Valve Disease. Specifically, Dr. Krieger compares the options of Mitral Valve Repair with Mitral Valve Replacement.
This video with Dr. Krieger is from a web cast at the Ronald O. Perelman Heart Institute at NewYork-Presbyterian.
VIEW VIDEOon Left Ventricular Assist Devices (LVADs) – Dr. Jonathan Chen
Dr. Jonathan Chen, the Site Chief for Pediatric Cardiac Surgery at NewYork-Presbyterian Hospital/Weill Cornell Medical Center in New York City, explains how Left Ventricular Assist Devices (LVADs) work and how they can benefit patients with heart failure.
LVADs are implantable devices that help the heart pump blood. They can be used as a temporary therapy, allowing patients’ hearts to rest while they recover from cardiac events such as heart attacks, or while they wait for hearts to become available for transplants. For some patients whose hearts are unlikely to recover and are not candidates for heart transplants, the devices may be used as a permanent therapy. Heart failure, especially in severe forms, can force patients to lead restricted lives because often even very limited physical activity, such as walking from one room to another, will leave them breathless.
Dr. Chen is a pediatric cardiothoracic surgeon, yet the information in the video is applicable to adult patients as well.
Organ transplantation that prolongs and dramatically improves quality of life is nearly a daily occurrence at Columbia University Medical Center.
The success of solid organ transplantation – with improved surgical techniques, replacement organ procurement, and medical management – is advancing each year. Many of these advances have resulted from scientific and clinical research conducted at Columbia University Medical Center.
A Brief History of Transplantation at Columbia
Transplantation: Where we’ve been, where we’re going
Eric A. Rose, MD, former chairman of the department of surgery, left center, performing the first successful pediatric heart transplant in 1984. Transplant pioneer Keith Reemtsma, MD, who is overseeing the operating field (top of photo).
When he transplanted a chimpanzee kidney into a human patient in the late 1960’s, the late Keith Reemtsma, MD, then Department of Surgery Chairman at Tulane University, revolutionized treatment of end-stage organ failure and initiated an era of unprecedented exploration into organ transplantation that would affect the lives of patients around the world.
Transferring to Columbia-Presbyterian Medical Center in 1971, Dr. Reemtsma recruited Mark A. Hardy, MD, who laid another cornerstone of organ transplant medicine by founding the program for dialysis and kidney transplantation. Dr. Hardy based the new program on the principle of collaborative clinical care between surgeons and nephrologists. During a time when renal transplant programs were managed by one or the other discipline but never by both simultaneously, the medical community regarded the concept as folly. Yet the program grew steadily, as did the program’s immune tolerance research initiatives to induce the transplant recipient’s body to accept a donor organ. This multidisciplinary cooperation also led to major contributions in immunogenetics, immunosuppression, and treatment of autoimmune diseases and lymphoma — and it ultimately became the overarching principle for all the NewYork-Presbyterian Hospital transplant services.
Colleagues universally give credit to Eric A. Rose, MD, who co-founded the heart transplantation program with Dr. Reemtsma, for his successful transformation of the program into the outstanding center it is today. A parade of achievements marks the history of the heart transplant program, including the first mechanical bridge-totransplantation using intra-aortic balloon pumps in the 1970’s, and the first successful pediatric heart transplant, performed by Dr. Rose in 1984. Under the guidance of Dr. Rose and his successors, the program has pioneered research in immunosuppressant medications, mechanical assist devices, and minimally invasive surgical procedures. It currently performs over 100 heart transplants yearly, with among the highest success rates in the nation.
Also in 2004, Lloyd E. Ratner, MD, succeeded Dr. Hardy as director of the renal and pancreas transplant program. One of the first to perform laparoscopic donor operations, Dr. Ratner has found creative solutions to overcome immune barriers to kidney transplantation. The program now routinely uses extended-criteria donor organs, performs transplants among incompatible donors, and is a leader in coordinating “donor swaps” to maximize availability of compatible donor organs. Since Dr. Ratner’s arrival, Columbia has been designated one of ten regional islet resource centers in the U.S. that isolate and transplant pancreatic cells to treat type 1 diabetes as part of a limited protocol controlled by the FDA. Recent progress in visualization of pancreatic islets using PET technology, under the guidance of Paul Harris, PhD, has been recognized by the scientific community as a milestone in this developing field.
NYPH/Columbia received UNOS approval for pancreatic transplantation in January 2008. Our premier kidney transplant program is facilitating rapid growth of the new pancreatic transplantation program, which overlaps both in its patient population and its surgical and medical expertise. The northeast region of the U.S. has been consistently underserved as far as access to pancreatic transplantation, with relatively few centers serving a disproportionately large metropolitan population. The expanding program at NewYork-Presbyterian now provides much-needed access to patients with end-stage pancreatic disease in New York state, particularly those with the most complex medical and surgical challenges.
Transplantation of cells, rather than organs, is emerging as a therapy with enormous potential. Transplantation of either a patient’s own or a foreign donor’s bone marrow cells, for example, offers hope of regenerating the heart so that patients with heart failure may be able to avoid heart transplantation.
In introducing the transplantation programs, it would be remiss to neglect mention of the yet another dimension in which they excel — education. Physician training is a top priority, and NYPH/Columbia has trained many of the greatest transplant surgeons over the last 20 years, including many of the leaders of transplant programs throughout the U.S.
At NewYork-Presbyterian Hospital/Columbia University Medical Center, the Transplant Initiative (TI) has been launched to drive the growth of both clinical and research aspects of transplantation. This multi-year undertaking will involve Departments of Medicine, Pathology, Pediatrics, and Surgery and all of the solid organ transplantation programs, both adult and pediatrics. It is led by its Executive Director, Jean C. Emond, MD.
Although NYP/Columbia is already a national leader in clinical transplantation with respect to volume and patient outcomes, this initiative will further leverage the diverse expertise of its transplant scientists and clinicians.
Approximately 2,200 heart transplants are now performed each year in more than 150 heart transplant centers in the United States. The surgeons and cardiologists of Columbia University Medical Center of NYPH have a long and distinguished history of advancing “standards of care” and the survival rates of our patients by using innovative surgical techniques, by applying our basic scientific research in immunosuppression to the clinical setting, and by inventing and perfecting life-sustaining cardiac assist devices that prolong life while waiting for organ availability.
Columbia University Medical Center’s lung and heart-lung transplantation program, which began in 1985, is fast approaching its 200th transplant. Performing more than 30 transplants each year, the lung and heart-lung transplant teams have earned a national reputation for excellence. Our world-renowned transplantation researchers have helped lead the way to improvements in care that, nationwide, have increased the long-term survival rate for lung transplantation by 50% over the past seven years. Among those improvements are new immunosuppressive agents, new antibiotics, refined surgical techniques, and a more comprehensive understanding of follow-up care.
It is the combination of basic research at the molecular cardiology level, biomaterial, surgical procedures and PUBLICATION of Cases and research results that found me in Dr. George’s territory as a renewed inspiration.
For Author’s training & experience @ MGH – Cardiac Floor – Ellison 11, BWH – CCU, Tower 3 – 12Fl, BIDMC – Acute Surgery, Farr 9, and Texas Heart Institute, Perfusion, Faulkner Hospital – ICU
Russo MJ, Chen JM, Sorabella RA, Martens TP, Garrido M, Davies RR, George I, Cheema FH, Mosca RS, Mital S, Ascheim DD, Argenziano M, Stewart AS, Oz MC, Naka Y.
Medtronic Garners First-Of-Its-Kind FDA Approval for ‘AUI’ Device with Endurant II AAA Stent Graft
MINNEAPOLIS — May 30, 2013 — Medtronic, Inc. (NYSE: MDT) is expanding its market-leading portfolio of products for endovascular aortic repair in the United States with two new medical devices: the company recently received approval from the U.S. Food and Drug Administration (FDA) for the Endurant II Aorto-Uni-Iliac (AUI) Stent Graft System and the FDA’s 510(k) clearance for the Sentrant Introducer Sheath; both devices will be on exhibit at the Medtronic booth during the Society for Vascular Surgery‘s “Vascular Annual Meeting,” which runs May 30-June 2 in San Francisco.
Endurant II AUI Stent Graft System
The Endurant II AUI Stent Graft System is the only FDA-approved AUI device in the United States indicated for the primary endovascular treatment of infrarenal abdominal aortic or aorto-iliac aneurysms in patients whose anatomy does not allow for the use of a bifurcated device. Both the bifurcated and AUI configurations of the Endurant Stent Graft System provide a new pathway for blood flow through the iliac arteries in abdominal aortic aneurysms, thereby reducing risk of aneurysm rupture.
Whereas use of the bifurcated device requires access to both iliac arteries, the AUI device requires access to only one iliac artery (Endurant II Aorto-Uni-Iliac (AUI)). In published studies of endovascular abdominal aortic aneurysm (AAA) repair.
Current global usage of AUI stent graft configurations averages
5 percent (range 0-26%) for intact AAA and
39 percent (range 0-91%) for ruptured AAA.[i],[ii]
“The new Endurant II Aorto-Uni-Iliac Stent Graft extends the proven performance of the Endurant System to patients with difficult access,” said Dr. Michel Makaroun, chief of vascular surgery at the University of Pittsburgh Medical Center and co-director of the UPMC Heart and Vascular Institute. “By maintaining the deliverability, conformability and deployment accuracy of the bifurcated Endurant device, the AUI configuration offers aneurysm patients with challenging outflow anatomies a better option for a successful endovascular aortic repair.”
As with the bifurcated Endurant II Stent Graft, distinguishing features of the Endurant II AUI Stent Graft include a low delivery profile, tip capture for easy and accurate deployment and compatibility with contralateral iliac limbs and aortic extensions for ultimate patient applicability.
Sentrant Introducer Sheath
The Sentrant Introducer Sheath complements Medtronic’s market-leading portfolio of stent grafts for endovascular aortic repair. It is specially designed for use with the Endurant II AAA and Valiant Captivia Stent Graft Systems and is also compatible with competitive systems. The Sentrant Introducer Sheath is inserted at the access site
in the patient’s femoral artery and advanced upwards into the iliac arteries to facilitate the implant procedure and enable smooth passage of the stent graft delivery system en route to the treatment site in the aorta.
The Sentrant Introducer Sheath can accommodate a wide range of anatomies, with diameters of 12-26 French and shaft lengths of 28cm. Other distinguishing features of the accessory device include:
optimal seal for superior hemostasis,
reinforced coil for kink resistance,
hydrophilic coating and
flexibility for easy tracking through tortuous and calcified iliacs and a
dilator locking mechanism for secure positioning.
The Sentrant Introducer Sheath received the CE (Conformité Européenne) mark in April 2013. Its FDA clearance expands the accessory device’s availability to endovascular specialists in the United States.
In collaboration with leading clinicians, researchers and scientists, Medtronic offers the broadest range of innovative medical technology for the interventional and surgical treatment of cardiovascular disease and cardiac arrhythmias. The company strives to offer products and services that deliver clinical and economic value to healthcare consumers and providers worldwide.
ABOUT MEDTRONIC
Medtronic, Inc. (www.medtronic.com), headquartered in Minneapolis, is the global leader in medical technology-alleviating pain, restoring health and extending life for millions of people around the world.
Any forward-looking statements are subject to risks and uncertainties such as those described in Medtronic’s periodic reports on file with the Securities and Exchange Commission. Actual results may differ materially from anticipated results.
As structural heart disease interventions continue to evolve to a sophisticated level, accurate and reliable imaging is required for pre-procedural selection of cases, intra-procedural guidance, post-procedural evaluation, and long-term follow-up of patients.
Traditionally, cardiovascular procedures in the catheterization laboratory are guided by fluoroscopy and angiography. Advances in echocardiography can overcome most limitations of conventional imaging modalities and provide successful completion of each step of any catheter–based treatment. Echocardiography’s unique characteristics rendered it the ideal technique for percutaneous catheter-based procedures.
The purpose of this review is to demonstrate the use of the most common and up-to-date echocardiographic techniques in recent non-coronary percutaneous interventional procedures, underlining its inevitable and growing role, as well as illustrating areas of weakness and limitations, and to provide future perspectives.
On March 7, 2013 a very significant, pending clearance event, in favor of Philips Healthcare, was announced:
U.S. FDA Clears Philips’ EchoNavigator for Fused TEE-Angiography Image Guidance
March 7, 2013
March 7, 2013 — Philips Healthcare announced it has received 510(k) clearance from the U.S. Food and Drug Administration (FDA) for its EchoNavigator live image-guidance tool. The technology helps interventional cardiologists and cardiac surgeons perform minimally invasive structural heart disease repairs by providing an intelligently integrated view of live X-ray and 3-D ultrasound images.
Following the CE marking of EchoNavigator in Europe, Philips will now be able to introduce the system globally, with systems already installed in Europe and the United States.
EchoNavigator was developed in response to an upward trend in the use of both X-ray imaging and 3-D cardiac ultrasound imaging (echocardiography) during structural heart disease procedures — an area of interventional cardiology that is growing at around 40 percent per year. During such procedures, ultrasound imaging provides critical insights into the heart’s soft tissue anatomy, while X-ray imaging has particular strengths in visualizing the catheters and heart implants. EchoNavigator was designed to address the unique challenges associated with working with live X-ray and 3-D ultrasound images simultaneously.
“Together with Philips, we set out to bring two separate medical imaging techniques together in a way that provides clear visual guidance,” said John Carroll, M.D., interventional cardiologist, University of Colorado Hospital, Denver. “EchoNavigator is enabling us to use X-ray images combined with real-time 3-D ultrasound images to navigate catheters and deploy implants in the right position in the heart, making such treatments more straightforward.”
EchoNavigator will enable clinicians to perform procedures more efficiently by providing intelligently integrated X-ray and 3-D ultrasound images into one intuitive and interactive view, as well as providing easy-to-use system navigation and better communication between the multidisciplinary team carrying out the procedure.
“We have learned that ideally two live imaging technologies are needed to guide catheter-based repairs to the heart, and a multidisciplinary team is needed to perform it,” said Roberto Corti, M.D., interventional cardiologist, University Hospital Zurich, Switzerland. “This adds to the complexity of such procedures. The development of a more sophisticated imaging technology such as EchoNavigator will definitely provide us with a better understanding of the complex structures of the heart and their repair.”
“As the global market leader in interventional cardiology, we have worked with our partners to lead the way with pioneering solutions such as our real-time 3-D ultrasound technology and more recently our HeartNavigator navigation tool,” said Gene Saragnese, CEO for Imaging Systems at Philips Healthcare. “EchoNavigator is further evidence of our commitment to transforming healthcare through the introduction of innovations that enable best in class minimally invasive procedures.”
“In the emerging field of complex structural heart disease interventions, the information obtained by merging imaging technologies, as now possible with HeartNavigator and EchoNavigator, will be of tremendous value to the interventionalist, and in turn to the patient,” said Carlos Ruiz, M.D., director of the structural and congenital heart disease program, department of interventional cardiology, Lenox Hill Hospital, New York.
3-D, 4-D Enhancements May Be the Future of Ultrasound
Written By:
Dave Fornell
May 15, 2012
A single-beat, short-axis 4-D echo imaged by GE’s Vivid E9. The system also offers software to reduce the number of clicks needed for exams. Photo courtesy of GE Healthcare
Hardware and software advances are enabling echocardiography to greatly expand its capability with increased quantification accuracy, ease-of-use, increased workflow efficiencies and wider use outside of echo labs. Today, cardiovascular ultrasound systems are being integrated into point-of-care for triage, and in operating rooms and cath labs for procedural guidance to cut the use of contrast and ionizing radiation. Advances in 4-D echo are making it an enhanced tool for structural heart evaluation and visualization during procedures.
3-D, 4-D Echo Advances
3-D echo images a volume of data (similar to a computed tomography [CT] dataset) rather than the traditional 2-D image rendering. These volumes can be manipulated with advanced visualization software just like a CT, slicing images on any plane and enabling the creation of 3-D images that can be rotated.
The proliferation of 3-D echo was previously handicapped by the large amount of labor involved in creating images from a volume dataset, explained Stephen Little, M.D., FRCPC, FACC, FASE, cardiovascular imaging section, department of cardiology, Methodist DeBakey. He said earlier generation systems required 30 or 40 mouse clicks to create an image.
“3-D required a lot of manual processing to slice and dice the images. It just took too long to do anything,” Little explained.
However, he said the newer 3-D systems are making the technology more viable with automation. He said echo is following the same path previously followed by CT advanced visualization software, where automation made a big difference in its wider market adoption for daily use.
Two big technology innovations have recently made 3-D and 4-D systems more commercially viable for everyday use. First, there has been a rapid increase in computing power in less expensive, smaller packages. Second, the automation of many advanced visualization functions drastically simplifies use and reduces the staff time required to manipulate volumes.
The introduction of 4-D echo (the fourth dimension is the addition of time) has opened new possibilities in ultrasound imaging. The analogy of 4-D is the difference between video and a still photograph. The technology allows 3-D images to be continuously updated for a live video view. The platforms with this feature require very fast processors to reconstruct large volumes of data into 3-D images over and over in milliseconds.
4-D ultrasound offers several advantages. It offers real-time color flow to assess hemodynamic information in the same heart cycle. It offers very accurate qualification of the left ventricle, free of geometric and shape assumptions used in 2-D echo. By using a 3-D volume of data, left ventricular wall motion tracking analysis can be done using the raw data volumes acquired. Vendors say this increases the accuracy of quantification.
It also offers multi-dimensional imaging, where operators can simultaneously acquire bi-plane and tri-plane images from the same heartbeat without moving the probe’s position. This offers two or three different axis views concurrently or as a composite view of the heart in real-time, offering a new field-of-view that previously could not be obtained. This helps acquire more information in fewer steps.
Real-time 4-D can produce images that are incredibly lifelike. This makes them easier to interpret and offers more meaningful information, including better procedural guidance. As technology continues to advance, 4-D echo will offer images comparable to CT 3-D reconstructions. Surgeons are now using 3-D echo reconstructions to aid procedural planning.
Use of 4-D greatly aids assessment of congenital heart diseases. Siemens recently introduced an updated version of its SC2000 cardiac ultrasound that quantifies volumetric color blood flow when evaluating holes in the heart (ASDs, VSDs, PFOs). The system uses a 3-D representation to show the true surface area and helps estimate the size of the holes for procedural planning.
Innovations in 4-D make possible real-time, comprehensive analysis of the beating heart during the entire cardiac cycle and allows even more detailed surgical-like views of the anatomy.
Toshiba’s new Aplio 500 shows the future of 4-D, where it can reconstruct volumes into color, fly-through video of vessel lumens. It works with peripheral vessels, but the heart is still too fast for the new technology to capture coronary vessels or ventricles. Image quality is similar to CT virtual colonoscopy.
Practical Application of 3-D
Methodist DeBakey Heart and Vascular Center has its own imaging center, which uses 3-D echo extensively. The center also images patients with both magnetic resonance imaging (MRI) and 3-D echo for comparative effectiveness research.
In the echo lab, 3-D echo is very good at estimating left ventricular ejection fractions (LVEF). However, there is a need for standardization between vendors before this technology will be used mainstream, Little said. Each 3-D echo machine is slightly different, so the workflow is not the same from vendor to vendor, and each requires use of proprietary workstations.
He explained 3-D offers a more accurate picture of cardiac function, but the basic concepts of 2-D echo still apply.
“3-D is not magic. It starts with a good 2-D image and you face all the same physics challenges as you do with 2-D technology,” Little said.
At DeBakey, echo contrast is often used to improve 2-D image quality when imaging obese patients, but they found 3-D has some limitations with contrast, said Miguel A. Quiñones, M.D., MACC, chairman, department of cardiology. The software uses automated 3-D tracking of the borders of the ventricle, he explained, but the automated tracking system is confused by the contrast and has issues. However, an operator can overcome this by switching to a manual mode.
Little said hospitals need to assess whether there is a need for 3-D. “It depends on what they plan to do with the system. If you plan to use it for surgical procedures, then it might be worth investing in a 3-D system. If you are involved in activities with more emphasis on structural heart, then 3-D has a lot of application.”
Expanding TEE Use
Little said DeBakey makes extensive use of 3-D echo transesophogeal echo (TEE) to better guide mitral valve prolapse and regurgitation repairs, atrial septal defects (ASDs) and trans-aortic valve repair (TAVR). In TAVR, he said TEE helps accurately place the angiographic pigtail catheter in the non-coronary cusp of the aortic root. It also offers Doppler flow imaging to evaluate the hemodynamics of the valves and check for paravalvular leaks.
Little explained 3-D TEE offers a definite imaging advantage during complex interventions. The use of an X-plane (also referred to as bi-plane) TEE probe allows visualization from two different angles. He said these views are displayed on the main screen in a cath lab or hybrid OR to better visualize where a catheter or device is located in the anatomy more clearly than 2-D angiography. This helps with procedural navigation and in cutting the radiation dose from fluoroscopy.
“You can get two views simultaneously from two different perspectives, which helps speed things up,” Little said. “It adds a level of confidence to show you where wires and devices are inside the heart.”
DeBakey uses 3-D echo from various vendors, including Philips, GE and Siemens, but only the Philips system had offered 3-D TEE, Little said.
Siemens recently introduced syngo FourSight 3-D TEE. It can scan the whole heart in one volume instead of stitching two or three images to create a whole-heart image.
GE Healthcare also has a new 4-D TEE system pending FDA review, which it previewed as a work-in-progress in March at American College of Cardiology (ACC) 2012 .
Comparison Chart
This article served as an introduction to the cardiovascular ultrasound systems comparison chart in the May-June 2012 issue of DAIC. Participants included:
New Software to aid Interventional Cardiologists and Cardiac Surgeons in TAVI Procedures.
We covered the procedure and the technologies in the following curated article:
Clinical Trials on transcatheter aortic valve replacement (TAVR) to be conducted by American College of Cardiology and the Society of Thoracic Surgeons
Philips received FDA clearance in December 2011 for its Heart Navigator TAVI planning and image guidance tool.
With the approval of the Sapien valve in November 2011, transcatheter aortic valve implantation (TAVI) technology is expected to revolutionize heart valve replacement with a minimally invasive procedure to replace open-heart surgery. However, it requires a good deal of planning, sizing and anatomical assessment of access routes using computed tomography (CT) scans with manipulation by advanced visualization software.
The success of this new procedure depends on correct patient selection and reliable pre-operative planning. In the conventional procedure, the necessary measurements are made during the actual surgery under direct visualization, but with TAVI, this can only be done pre-operatively with the aid of image data. A clear appreciation of the involved anatomy is crucial, and due to the fact that aortic anatomy is complex, 3-D visualization and measurement tools may enable more accurate and efficient pre- and post-intervention planning, which can be further enhanced with stereoscopic 3-D.At the 2011 Radiological Society of North America (RSNA) annual meeting, TeraRecon and Qi Imaging (formerly Ziosoft) both unveiled TAVI planning and tool set software packages. The software helps automate manipulation of a CT dataset to quickly extract only the anatomy of interest and measurements, such as sizing of the aortic valve annulus and evaluation of clearance between the new valve and the right and left main coronary arteries. The software helps evaluate the aortic anatomy of patients to see if the route is clear for the larger delivery catheters required for the procedure. A heavily calcified aorta may disqualify a patient from the femoral access route.
Qi Imaging applied its super-computing, deformable registration software to its TAVI package, allowing lifelike motion of the cardiac cycle. This may offer a more accurate assessment of the motion of annulus for better valve sizing.
Philips Healthcare received FDA clearance in December for its HeartNavigator procedure planning and image guidance tool to help perform minimally invasive heart valve replacements. The technology merges pre-operatively acquired 3-D CT scans of the patient’s heart with the live interventional X-ray views. Using this technology, physicians can now simultaneously see the detailed 3-D anatomy of the patient’s heart together with the positioning of the catheter and the placement and deployment of the artificial valve. TAVI has been available in Europe since March 2010. In August 2010, Siemens introduced its syngo Aortic ValveGuide in Europe to aid in TAVI procedures. It uses rotational angiography dataset images in the hybrid OR to help surgeons and interventional cardiologists navigate during transcatheter valve implantations. The software processes CT-like images of the heart from images acquired with the angiography system and creates 3-D overlay images on the live fluoroscopy. The software also finds the correct optimal C-arm angulation with a perpendicular view on the aortic root.
Siemens’ syngo Aortic ValveGuide aids TAVI navigation with rotational angiography image overlays.
Imaging-biomarkers is Imaging-based tissue characterization
Author – Writer: Dror Nir, PhD
Article 11.1 Introduction by Dror Nir PhD
For everyone who is skeptical about the future role of imaging-based tissue chracterisation in the management of cancer, the following “Statement paper” ESR statement on the stepwise development of imaging biomarkers published online: 9 February 2013, by the European Society of Radiology (ESR), should provide substantial reassurance that this kind of technology will become a must! In support of this claim I quote the following information:
“The European Society of Radiology and its related European Institute for Biomedical Imaging Research (EIBIR) should have a relevant role in coordinating future developments of biomarkers and in the assessment and validation of imaging biomarkers as surrogate end points.
Acknowledgements
This paper was kindly prepared by the ESR Subcommittee on Imaging Biomarkers (Chairperson: Bernard Van Beers. Research Committee Chairperson: Luis Martí-Bonmatí. Members: Marco Essig, Thomas Helbich, Celso Matos, Wiro Niessen, Anwar Padhani, Harriet C. Thoeny, Siegfried Trattnig, Jean-Paul Vallée. Co-opted members: Peter Brader, Nicolas Grenier) on behalf of the European Society of Radiology (ESR) and with the help of Sabrina Doblas, INSERM U773, Paris, France.
It was approved by the ESR Executive Council in December 2012..”
According to ESR: “There is increasing interest in developing the quantitative imaging of biomarkers in personalised medicine”. In this perspective, “Biomarkers” are tissue properties that can be quantitatively and reproducibly measured by imaging devices. One example for a major unmet need, which I found to be most interesting is the imaging-based detection of tumor invasiveness.
Quoting from the paper: ” Biomarkers are defined as “characteristics that are objectively measured and evaluated as indicators of normal biological processes, pathological processes, or pharmaceutical responses to a therapeutic intervention” [1]. Broadly, biomarkers fall into two categories: bio-specimen biomarkers, including molecular biomarkers and genetic biomarkers, and bio-signal biomarkers or imaging biomarkers. Bio-specimen biomarkers are obtained by removing a sample from a patient. Examples of these molecular biomarkers are genes and proteins detected from fluids or tissue samples. Bio-signal biomarkers remove no material from the patient, but rather detect and analyse an electromagnetic, photonic or acoustic signal emitted by the patient [2]. These imaging biomarkershave the advantage of being non-invasive, spatially resolved and repeatable [3]. They are of particular interest if they can overcome the limitations of the established histological “gold standards”. Indeed, invasive reference examinations, such as biopsy, can be inconclusive, are non-representative of the whole tissue (which is a tremendous limitation when assessing malignant tumours, which are known to be heterogeneous) and possess non-negligible levels of mortality and morbidity.
Genetic biomarkers indicate whether a disease may occur, but they are usually inefficient to assess the presence and stage of a disease. Similar to molecular biomarkers, imaging biomarkers can be used for early detection of diseases, staging and grading, and predicting or assessing the response to treatment [3]. Accordingly, because of their relative lower cost compared with imaging, molecular biomarkers may be more appropriate for disease screening and early detection than imaging biomarkers. With their high sensitivity, molecular biomarkers could also detect subclinical stages of disease before any morphological or functional change is detectable on imaging. In contrast, imaging biomarkers are often more useful than molecular biomarkers for disease staging, and also grading and for assessing tumour response, because localised information is crucial.”
The main messages ESR wishes to deliver in this paper are that:
• Using imaging-biomarkers to streamline drug discovery and disease progression will drive a huge advancement in healthcare.
• The clinical qualification and validation of imaging biomarkers technology pose challenges, mainly in establishing the accuracy and reproducibility of such techniques. In that respect, agreements on standards and evaluation methods (e.g. clinical studies design) is imperative.
• There should be high motivation to pursue the development of imaging-biomarkers as the “clinical value of new biomarkers is of the highest priority in terms of patient management, assessing risk factors and disease prognosis.”
The paper deals to a great extent with the requirements on accuracy, reproducibility, standardization and quality control from the process of developing imaging-biomarkers:
“Accuracy: Before being routinely used in the clinic, imaging biomarkers must be validated. Determining the accuracy implies calculating the sensitivity and specificity of the biomarker when compared with a biological process, such as tumour necrosis, which can be assessed at histopathological examination… [6–9] [10,11]
Reproducibility: Repeatability (measurements at short intervals on the same subjects using the same equipment in the same centres) and reproducibility (measurements at short intervals on the same subjects using different facilities in the same and different centres) studies must be conducted for image acquisition and image analysis…. Reproducibility studies are now very often included in scientific papers, as advised by the “standards for reporting of diagnostic accuracy” (STARD) criteria and should ideally include Bland-Altman plots and results of coefficients of repeatability [16, 17].
Standardisation: Standardisation relates to the establishment of norms or requirements about technical aspects. In the development of imaging biomarkers, two main aspects should be considered: Standardisation of image acquisition and Standardisation of image analysis…[18][19–21][22] [27,28] [31–33]
Quality control: Adequate phantoms could be used to validate, on a day-to-day basis, that the biomarker stays robust and to avoid any drift in the machine, acquisition or processing protocol…. [34] [30, 35] [36] [37] [23].”
The proposed development workflow:
“Similar to new drugs, the development of biomarkers has to pass along a pipeline going from discovery, through verification in different laboratories, validation and qualification before they can be used in clinical routine. Validation includes the determination of the accuracy and the precision (reproducibility) of the biomarker and standardisation concerns both acquisition and analysis. Qualification, defined as a “graded, fit-for-purpose evidentiary process linking a biomarker with biological processes and clinical end-points”, is a validation process in large cohorts of patients involving multiple centres, similar to phase III clinical trials, to obtain regulatory approval as surrogate endpoints [4]. A more extensive path to biomarker development has been reported [5]. The first step is the proof of concept, which defines any specific change relevant to the disease that can be studied using the available imaging and computational techniques. The relationship between this change and the presence, grading and response to treatment of the disease constitutes the proof of mechanism. The images needed to extract the biomarker must be appropriate (in terms of resolution, signal and contrast behaviour). Preparation of images relates to improving the data before the analysis (such as segmentation, filtering, interpolation or registration). The analysis and modelling of the signal by computational numerical adjustment of a mathematical model allow extracting the needed information (such as structural, physical, chemical, biological and functional properties). After this voxel-by-voxel computation, the spatial distribution of the biomarker can be depicted by parametric images, defined as derived secondary images which pixels represent the distribution values of a given parameter. Multivariate parametric images obtained by statistical modelling of the relevant parameters allow the reduction of data and a clear definition of the defined disease target. The abnormal values should be defined and measured through histogram analysis. A pilot test on a small sample of subjects, with and without the disease, has to be performed to validate the process—also called proof of principle—and to evaluate the influence of potential variations related to age, sex or any other source of biases. Finally, proofs of efficacy and effectiveness on larger and well-defined series of patients will show the ability of a biomarker to measure the clinical endpoint (Fig. 1).”
Steps for the development of imaging biomarkers (adapted from [5])
The authors admit that the requirement posed on development of imaging-biomarkers represents a huge challenge and they try to offer ideas, mainly taken from the “MRI experience” to overcome certain hurdles. There is one important point on which they do not discuss: the definition of appropriate reference test. It is my own experience, based on many study protocols I developed in the past decade, that without reaching an agreement on that point, the development of imaging-biomarkers will just move in circles. Note, that today’s most “acceptable” reference test is histopathology, which everyone admits (as well mentioned in this paper); suffers many limitations. When it comes to validating imaging-biomarkers, the need to accurately match imaging products with histopathology is an additional major hurdle.
This is why, I see as a necessary step, to develop “real-time” imaging based tissue characterization combined with in-situ imaging-based histology.
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Though I wonder why Edwards would be taking a more than 30 year-old medical device to China – only Edwards’ business leaders could answer that – I was stuck by one small paragraph that led to this writing.
“Edwards, like many device companies, has turned to China for new growth opportunities and the country factors into its long-term growth plans. Known for heart valves and hemodynamic monitoring devices, Edwards has also propelled U.S. growth with its Sapien transcatheter aortic heart valve, which won FDA approval earlier this fall to treat a larger class of patients.”
This discussion will address the current trend of Western companies attempting to penetrate China’s medical device market. As one who is often asked to speak at public meetings on this topic, I have given frequent and serious reflection on my experiences with and knowledge of this topic.
The uninitiated Western medical device companies may not realize that China is very much different from other major countries, in the areas of
marketing/sales,
regulatory affairs,
clinical research, and
hospital practices.
Historically, SFDA has been active since the 1990’s; however, their initial focus was limited to understanding and approving pharmaceuticals. Thus, SFDA’s
regulations,
extent of product and therapeutic knowledge, and
GCP certification programs
have been primarily focused on drugs. With the exception of the counterfeit medicine epidemic, global pharmaceutical companies have become well entrenched and enjoy a strong presence in China’s hospitals. That does not mean they are making great profits.
Counterfeit drug enterprises in China have steadily grown into a lucrative opportunity since the 1990s. Often supported by local government and Chinese Military investment, counterfeit drug manufacturing plants can be rapidly set up and also re-established, if subjected to raids by SFDA officials. These fake medications have found their way into China’s pharmacies and hospitals, and now are a threat to the United States.The loss of bona fide sales as well as the money required to fight this criminal element significantly erodes the profits of major pharmaceutical companies.
In and above the aforementioned challenge to global pharmaceutical companies, all biomedical companies must share a considerable portion of any given patient population with Chinese Traditional Medicine (CTM). CTM has enjoyed centuries of development and use and it is an integral part of China’s society. Medical schools and hospitals teach and offer CTM therapies. Given the paucity of health insurance among the majority of China’s population and limited disposable income to pay for expensive medical treatments, CTM offers an attractive alternative – one that is deeply entrenched within the culture and also easily affordable. For reasons to which I will allude later, CTM lends itself to a culture that readily accepts anecdotal evidence and rarely scrutinizes medical therapies for compelling clinical evidence.
Medical devices have their own unique challenges to address. Initially, many of them are not readily apparent to any neophyte company that expects ‘business as usual’ when introducing products to China. Unlike Japan, where one of the biggest barriers to market entry rests in dealing with a well-organized, challenging, and complex regulatory authority, SFDA is a ‘work in progress’. China is the only country, of which I am aware, where the regulatory authority (SFDA) has asked experts in global companies for helpful guidance on the approval and oversight of medical devices. Couple that with the national governments focus on making it easier for Chinese medical device companies to access the market, and it’s easy to understand why several large home-born enterprises, such as Microport Medical, enjoy large shares of the domestic market for most indications.
For many years, and even today, many companies refuse to go to China for fear of having their technology reverse engineered and copied. This fear is fueled by China’s lack of effective laws on intellectual property (IP). Even where laws do exist, they are rarely enforced. This fear on the part of Western companies is irrational, which is why the major global medical device companies and many smaller organizations, including Edwards LifeSciences, have concluded that threats to their IP are no more an issue in China than in any other region of the world.
That is not to say copycat devices don’t exist in China. Many observers are curious as to how these large domestic medical device companies in China could have product portfolios that closely replicate those of the major global companies. To illustrate this point – during the 1990s, I knew a Chinese woman in Southern California who worked in QA and, therefore, had access to drawings, test results, and manufacturing processes for any of her current company’s product portfolios. Her open confession to me was that, after another year or so, she planned to go back to China to establish her own catheter company, using all the knowledge and information she had gathered in her job. Western media have uncovered a lot of copying of company proprietary information by Chinese citizens who find jobs in the USA or Europe. Many ‘industrial spies’ are highly qualified engineers and scientists who make valuable contributions to all aspects of product development. In spite of their devotion to product development, one can understand their culturally-inbred insensitivity toward issues of confidentiality and intellectual property.
Some readers might be thinking right now, “Damned if you do!” (going to China) and “Damned if you don’t!” (opting to stay in a protective mode outside China). Some might conclude that, if Western countries open up their doors to foreign engineers and scientists, no IP is safe. However, one only has to look at WL Gore (Flagstaff AZ), which experienced an American-bred and educated manufacturing ‘associate’ relocating down the mountain to Phoenix to establish a company that was alleged to have incorporated biomaterials, knowhow, and manufacturing processes inherent to Gore. Though the latter is uncommon, it does underscore the point that industrial espionage is not just a China-based challenge; however, in most Western countries, rigorous enforcement of strict IP laws is quite effective in keeping ‘copycat’ medical devices, including those that originate in China, off the market. Given this perspective, avoiding China only for fear of IP threats is irrational.
In September 2012, in Northern California, I met with a VP of International Business for one of the largest of China’s domestic medical device companies. I was curious about his company having no presence in the U.S. market and their international focus on African and South American countries – both regions being weak in enforcing laws on IP. Given his company’s limited global focus and his admission that the company leadership in Shanghai only understood China’s processes and had no appreciation of or interest in appropriate development and expensive testing of medical devices sufficient to achieve CE Mark or 510(k) clearance, Western medical device business leaders can breathe easy about the prospect of a company in China threatening market share in Europe, USA and many other Western countries with copycat devices.
This is just one of several instances where China’s culture and laws are deeply entrenched in the medical device community, resulting in unique perspectives and practices. Some of these differences and limitations make it very difficult for China’s physicians to compete with their Western counterparts in such areas as publishing in Western peer-reviewed medical journals and in carrying out quality research with medical devices.A significant challenge for Western medical device companies is to assure that their China-trained customers have sufficient skills to use their devices. Two-day training programs for physicians have proven to be quite ineffective.
There are many endemic factors, which contribute to the lack of sufficient technical skill and therapeutic proficiency on the part of China’s medical device users. Some of these are
(a) strong tendency to be dogmatic and carry on with older therapeutic approaches (justification is based on having treated large numbers of patients with long-established methods);
(b) hospital hierarchical management style, with older physicians at the top who direct all staff members to propagate older methods;
(c) medical school training does not include experience with newer medical devices;
(d) Western medical devices are often sold at Western prices, leaving so many uninsured patients unable to pay for these therapies (limited use of Western devices); and,
(e) the role of CTM further erodes opportunities to get valuable experience.
Edwards LifeSciences may enjoy early market penetration with a 30-year-old heart valve. Most companies initially focus on
Beijing,
Shanghai,
Guangzhou and
a few other major cities,
where more patients have health insurance and/or sufficient cash to pay for expensive treatments. But, to gain major market share, prices would have to come down dramatically, something many multi-national medical device companies are reluctant to consider.
The above comments are only a cursory reflection of some of the key challenges facing a company interested in the medical device market in China. I have not mentioned the unique challenges for
marketing and
distribution or the rather unique approach one must adopt to
sponsor and manage clinical trials in China.
A STORY OF LAGGING BEHIND:
For more than a decade, medical device applications, modernization, and market expansion in China have lagged well behind a more mature pharmaceutical domain. Compounding this is another gap created between a hierarchical, dogmatic, and historically/culturally-entrenched medical communityand those components of China’s society (examples are, IT, capitalism, banking, fashion) that have dramaticall expanded, modernized, and brought economic prosperity. I believe that the aforementioned gaps have narrowed in recent years and can be increasingly narrowed such that many Western medical devices will find a formidable market presence in China.
Other related articles on Medical Devices for Cardiac Repair published on this Open Access Online Scientific Journal. include the following:
August 7, 2012 – Transcatheter Aortic Valve Implantation (TAVI): risk for stroke and suitability for surgery
6/19/2012Executive Compensation and Comparator Group Definition in the Cardiac and Vascular Medical Devices Sector: A Bright Future for Edwards Lifesciences Corporation in the Transcatheter Heart Valve Replacement Market
2/12/2013 Clinical Trials on transcatheter aortic valve replacement (TAVR) to be conducted by American College of Cardiology and the Society of Thoracic Surgeons
Direct Flow Medical Wins European Clearance for Catheter Delivered Aortic Valve
Reporter: Aviva Lev-Ari, PhD, RN
UPDATED on 7/15/2018
Direct Flow Medical, which markets a CE-marked transcatheter aortic valve implantation (TAVI) device, has closed after funding from a Chinese pharmaceutical company did not come through. According to newspaper The Press Democrat, all 250 company’s employees have been made redundant and it officially ceased trading on 30 November.
The paper reports that Direct Flow’s former president and chief executive officer Dan Lemaitre, in a phone interview, told them the company had expected an influx of funding from a Chinese pharmaceutical company on 18 November but the deal collapsed two days before the money was scheduled to arrive. Lemaitre said this was because “the terms of which were changed dramatically in a very unacceptable fashion.”
The Press Democrat claims that the 12-year-old company had no other options and its lender—PDL BioPharma Inc—refused to extend the US$65 million funding arrangement it had with Direct Flow for the past three years and foreclosed upon the business.
Having unveiled attractive results of a study on its transcatheter aortic valve, Direct Flow Medical (Santa Rosa, CA) has just announced CE Mark approval for the device. The polymer frame prosthesis sits on top of the diseased natural valve with its inflatable rings guaranteeing contact along the perimeter.
Since the new valve only uses physical pressure from the inflatable rings to hold on, it can be repositioned at any time or removed completely if necessary.
Here’s more about the valve from its product page:
The bovine pericardial leaflets are attached to an inflatable polyester fabric cuff which conforms to the native aortic valve annulus and left ventricular outflow tract to form a seal to minimize the potential of paravalvular leak. The Bioprosthesis is designed with independently inflatable ventricular and aortic rings, which encircle and capture the native valve annulus to provide positive axial anchoring of the device. Inflation of the cuff with a saline and contrast solution renders the valve immediately functional and permits fluoroscopic visualization. Before final deployment, the saline and contrast mixture is exchanged under pressure, maintaining cuff shape and position, with a solidifying Polymer that hardens to form the permanent support structure.
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