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Live Notes, Real Time Conference Coverage 2020 AACR Virtual Meeting April 27, 2020 Opening Remarks and Clinical Session 11:45am-1:15pm Advances in Cancer Drug Discovery

Posted in Cancer - General, Cancer and Current Therapeutics, CANCER BIOLOGY & Innovations in Cancer Therapy, Conference Coverage with Social Media, Curation, Drug Delivery Platform Technology, Drug Development Process, Drug Discovery Chemistry, Pharmaceutical Drug Discovery, Pharmaceutical Industry Competitive Intelligence, Pharmaceutical R&D Investment, Pharmacodynamics and Pharmacokinetics, REAL TIME Conference Coverage Twitter's Hashtags and Handles per Presentation/session, Scientific & Biotech Conferences: Press Coverage, Small Molecules in Development of Therapeutic Drugs, tagged #pharmanews, @Biotech News, AACR, American Association for Cancer Research, Cancer, Estrogen receptor alpha, pharmacokinetic, Pharmacokinetics, real time conference coverage, SHP2, small drug development on April 27, 2020| Leave a Comment »

Live Notes, Real Time Conference Coverage 2020 AACR Virtual Meeting April 27, 2020 Opening Remarks and Clinical Session 11:45am-1:15pm Advances in Cancer Drug Discovery

SESSION VMS.CH01.01 – Advances in Cancer Drug Design and Discovery

April 27, 2020, 11:45 AM – 1:15 PM
Virtual Meeting: All Session Times Are U.S. EDT
DESCRIPTIONAll session times are U.S. Eastern Daylight Time (EDT).

Session Type
Virtual Minisymposium
Track(s)
Cancer Chemistry
14 Presentations
11:45 AM – 11:45 AM
– ChairpersonZoran Rankovic. St. Jude Children’s Research Hospital, Memphis, TN

11:45 AM – 11:45 AM
– ChairpersonChristopher G. Nasveschuk. C4 Therapeutics, Watertown, MA

11:45 AM – 11:50 AM
– IntroductionZoran Rankovic. St. Jude Children’s Research Hospital, Memphis, TN

11:50 AM – 12:00 PM
1036 – Discovery of a highly potent, efficacious and orally active small-molecule inhibitor of embryonic ectoderm development (EED)Changwei Wang, Rohan Kalyan Rej, Jianfeng Lu, Mi Wang, Kaitlin P. Harvey, Chao-Yie Yang, Ester Fernandez-Salas, Jeanne Stuckey, Elyse Petrunak, Caroline Foster, Yunlong Zhou, Rubin Zhou, Guozhi Tang, Jianyong Chen, Shaomeng Wang. Rogel Cancer Center and Departments of Internal Medicine, Pharmacology, and Medicinal Chemistry, Life Sciences Institute, University of Michigan, Ann Arbor, MI, Ascentage Pharma Group, Taizhou, Jiangsu, China

12:00 PM – 12:05 PM
– Discussion

12:05 PM – 12:15 PM
1037 – Orally available small molecule CD73 inhibitor reverses immunosuppression through blocking of adenosine productionXiaohui Du, Brian Blank, Brenda Chan, Xi Chen, Yuping Chen, Frank Duong, Lori Friedman, Tom Huang, Melissa R. Junttila, Wayne Kong, Todd Metzger, Jared Moore, Daqing Sun, Jessica Sun, Dena Sutimantanapi, Natalie Yuen, Tatiana Zavorotinskaya. ORIC Pharmaceuticals, South San Francisco, CA, ORIC Pharmaceuticals, South San Francisco, CA, ORIC Pharmaceuticals, South San Francisco, CA, ORIC Pharmaceuticals, South San Francisco, CA

12:15 PM – 12:20 PM
– Discussion

12:20 PM – 12:30 PM
1038 – A potent and selective PARP14 inhibitor decreases pro-tumor macrophage function and elicits inflammatory responses in tumor explantsLaurie Schenkel, Jennifer Molina, Kerren Swinger, Ryan Abo, Danielle Blackwell, Anne Cheung, William Church, Kristy Kuplast-Barr, Alvin Lu, Elena Minissale, Mario Niepel, Melissa Vasbinder, Tim Wigle, Victoria Richon, Heike Keilhack, Kevin Kuntz. Ribon Therapeutics, Cambridge, MA

12:30 PM – 12:35 PM
– Discussion

12:35 PM – 12:45 PM
1039 – Fragment-based drug discovery to identify small molecule allosteric inhibitors of SHP2. Philip J. Day, Valerio Berdini, Juan Castro, Gianni Chessari, Thomas G. Davies, James E. H. Day, Satoshi Fukaya, Chris Hamlett, Keisha Hearn, Steve Hiscock, Rhian Holvey, Satoru Ito, Yasuo Kodama, Kenichi Matsuo, Yoko Nakatsuru, Nick Palmer, Amanda Price, Tadashi Shimamura, Jeffrey D. St. Denis, Nicola G. Wallis, Glyn Williams, Christopher N. Johnson. Astex Pharmaceuticals, Inc., Cambridge, United Kingdom, Taiho Pharmaceutical Co., Ltd, Tsukuba, Japan

Abstract: The ubiquitously expressed protein tyrosine phosphatase SHP2 is required for signalling downstream of receptor tyrosine kinases (RTKs) and plays a role in regulating many cellular processes. Recent advances have shown that genetic knockdown and pharmacological inhibition of SHP2 suppresses RAS/MAPK signalling and inhibits proliferation of RTK-driven cancer cell lines. SHP2 is now understood to act upstream of RAS and plays a role in KRAS-driven cancers, an area of research which is rapidly growing. Considering that RTK deregulation often leads to a wide range of cancers and the newly appreciated role of SHP2 in KRAS-driven cancers, SHP2 inhibitors are therefore a promising therapeutic approach.
SHP2 contains two N-terminal tandem SH2 domains (N-SH2, C-SH2), a catalytic phosphatase domain and a C-terminal tail. SHP2 switches between “open” active and “closed” inactive forms due to autoinhibitory interactions between the N-SH2 domain and the phosphatase domain. Historically, phosphatases were deemed undruggable as there had been no advancements with active site inhibitors. We hypothesised that fragment screening would be highly applicable and amenable to this target to enable alternative means of inhibition through identification of allosteric binding sites. Here we describe the first reported fragment screen against SHP2.
Using our fragment-based Pyramid^TM approach, screening was carried out on two constructs of SHP2; a closed autoinhibited C-terminal truncated form (phosphatase and both SH2 domains), as well as the phosphatase-only domain. A combination of screening methods such as X-ray crystallography and NMR were employed to identify fragment hits at multiple sites on SHP2, including the tunnel-like allosteric site reported by Chen et al, 2016. Initial fragment hits had affinities for SHP2 in the range of 1mM as measured by ITC. Binding of these hits was improved using structure-guided design to generate compounds which inhibit SHP2 phosphatase activity and are promising starting points for further optimization.

anti estrogen receptor therapy: ER degraders is one class
AZ9833 enhances degradation of ER alpha
worked in preclinical mouse model (however very specific)
PK parameters were good for orally available in rodents; also in vitro and in vivo correlation correlated in rats but not in dogs so they were not sure if good to go in humans
they were below Km in rats but already at saturated in dogs, dogs were high clearance
predicted human bioavailability at 40%

12:45 PM – 12:50 PM
– Discussion

12:50 PM – 1:00 PM
1042 – Preclinical pharmacokinetic and metabolic characterization of the next generation oral SERD AZD9833Eric T. Gangl, Roshini Markandu, Pradeep Sharma, Andy Sykes, Petar Pop-Damkov, Pablo Morentin Gutierrez, James S. Scott, Dermot F. McGinnity, Adrian J. Fretland, Teresa Klinowska. AstraZeneca, Waltham, MA

1:00 PM – 1:05 PM
– Discussion

1:05 PM – 1:15 PM
– Closing RemarksChristopher G. Nasveschuk. MA

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Drug Eluting Stents: On MIT’s Edelman Lab’s Contributions to Vascular Biology and its Pioneering Research on DES

Posted in Alzheimer's Disease, Atherogenic Processes & Pathology, Bio Instrumentation in Experimental Life Sciences Research, Biological Networks, Gene Regulation and Evolution, Biomarkers & Medical Diagnostics, Cardiac & Vascular Repair Tools Subsegment, Cardiovascular Pharmacogenomics, Cell Biology, Signaling & Cell Circuits, Computational Biology/Systems and Bioinformatics, Drug Delivery Platform Technology, Ecosystems & Industrial Concentration in the Medical Device Sector, Etiology, Frontiers in Cardiology and Cardiovascular Disorders, Genome Biology, Glycobiology: Biopharmaceutical Production, Pharmacodynamics and Pharmacokinetics, HTN, Human Immune System in Health and in Disease, International Global Work in Pharmaceutical, Medical Devices R&D and Inventions, Medical Devices R&D Investment, Molecular Genetics & Pharmaceutical, Nitric Oxide in Health and Disease, Origins of Cardiovascular Disease, PCI, Personalized and Precision Medicine & Genomic Research, Pharmaceutical Industry Competitive Intelligence, Pharmaceutical R&D Investment, Pharmacotherapy of Cardiovascular Disease, Population Health Management, Genetics & Pharmaceutical, Population Health Management, Nutrition and Phytochemistry, Regulated Clinical Trials: Design, Methods, Components and IRB related issues, Resident-cell-based, Statistical Methods for Research Evaluation, Stem Cells for Regenerative Medicine, Stents & Tools, Systemic Inflammatory Response Related Disorders, Technology Transfer: Biotech and Pharmaceutical, tagged 3D-biomatrix, arterial lumin, Atherosclerosis, Basic fibroblast growth factor, Biology, Blood vessel, drug binding, Drug delivery, drug distribution, Drug-eluting stent, endothelial damage, Harvard Medical School, heparan-sulfate, heparin, Larry H. Bernstein, macrophages, medial hyperplasia, perivascular effect, Pharmacokinetics, proximity of delivery, Smooth muscle tissue, Stent, subintimal inflammation, subintimal plaque, Vascular smooth muscle on April 25, 2013| 18 Comments »

Drug Eluting Stents: On MIT‘s Edelman Lab’s Contributions to Vascular Biology and its Pioneering Research on DES

Author: Larry H Bernstein, MD, FACP

and

Curator: Aviva Lev-Ari, PhD, RN
http://PharmaceuticalIntelligence.com/2013/04/25/Contributions
-to-vascular-biology/

This is the first of a three part series on the evolution of vascular biology and the studies of the effects of biomaterials in vascular reconstruction and on drug delivery, which has embraced a collaboration of cardiologists at Harvard Medical School , Affiliated Hospitals, and MIT, requiring cardiovascular scientists at the PhD and MD level, physicists, and computational biologists working in concert, and an exploration of the depth of the contributions by a distinguished physician, scientist, and thinker.

The first part – Vascular Biology and Disease – will cover the advances in the research on

vascular biology,
signaling pathways,
drug diffusion across the endothelium and
the interactions with the underlying muscularis (media),
with additional considerations for type 2 diabetes mellitus.

The second part – Stents and Drug Delivery – will cover the

purposes,
properties and
evolution of stent technology with
the acquired knowledge of the pharmacodynamics of drug interactions and drug distribution.

The third part – Problems and Promise of Biomaterials Technology – will cover the shortcomings of the cardiovascular devices, and opportunities for improvement

Vascular Biology and Cardiovascular Disease

Early work on endothelial injury and drug release principles

The insertion of a catheter for the administration of heparin is not an innocuous procedure. Heparin is infused to block coagulation, lowering the risk of a dangerous

clot formation and
dissemination.

It was shown experimentally that the continuous infusion of heparin

suppresses smooth muscle proliferation after endothelial injury. It may lead to
hemorrhage as a primary effect.

The anticoagulant property of heparin was removed by chemical modification without loss of the anti-proliferative effect.

In this study, MIT researches placed ethylene-vinyl acetate copolymer matrices containing standard and modified heparin adjacent to rat carotid arteries at the time of balloon deendothelialization.

Matrix delivery of both heparin compounds effectively diminished this proliferation in comparison to controls without producing systemic anticoagulation or side effects.

This mode of therapy appeared more effective than administering the agents by either

intravenous pumps or

heparin/polymer matrices placed in a subcutaneous site distant from the injured carotid artery

This indicated that the site of placement at the site of injury is a factor in the microenvironment, and is a preference for avoiding restenosis after angioplasty and other interventions.

This raised the question of why the proliferation of vascular muscle occurs in the first place.  Edelman, Nugent and Karnovsky (1) showed that the proliferation required first the denudation of vascular surface endothelium. This exposed the underlayer to the effect of basic fibroblast growth factor, which stimulates mitogenesis of the exposed cell, explained by the endothelium as a barrier from circulating bFGF.

To answer this question, they compared the effect of

125I-labelled bFGF intravenously given with perivascular controlled bFGF release.
Polymeric controlled release devices delivered bFGF to the extravascular space without transendothelial transport.  Deposition within the blood vessel wall was rapidly distributed circumferentially and was substantially greater than that observed following intravenous injection.

The amount of bFGF deposited in arteries adjacent to the release devices was 40 times that deposited in similar arteries in animals who received a single intravenous bolus of bFGF.

The presence of intimal hyperplasia increased deposition of perivascularly released bFGF 2.4-fold but decreased the deposition of intravenously injected bFGF by 67%.

bFGF was 5- to 30-fold more abundant in solid organs after intravenous injection than it was following perivascular release, and
bFGF deposition was greatest in the kidney, liver, and spleen and was substantially lower in the heart and lung.

This result indicated that vascular deposition of bFGF is independent of endothelium, and

bFGF delivery is effectively perivascular. (2)

Drug activity studies have to be done in well controlled and representative conditions.  Edelsman’s Lab researchers studied the

dose response of injured arteries to exogenous heparin in vivo by providing steady and predictable arterial levels of drug.
Controlled-release devices were fabricated to direct heparin uniformly and at a steady rate to the adventitial surface of balloon-injured rat carotid arteries.

Researchers predicted the distribution of heparin throughout the arterial wall using computational simulations and correlated these concentrations with the biologic response of the tissues.

Researchers determined from this process that an in vivo arterial concentration of 0.3 mg/ml of heparin is required to maximallyinhibit intimal hyperplasia after injury.

This estimation of the required tissue concentration of a drug is

independent of the route of administration and
applies to all forms of drug release.

In this way the Team was able to

evaluate the potential of widely disparate forms of drug release and, to finally
create some rigorous criteria by which to guide the development of particular delivery strategies for local diseases. (3)

Chiefly, the following three effects:

(1) Effect of controlled adventitial heparin delivery on smooth muscle cell proliferation following endothelial injury. ER Edelman, DH Adams, and MJ Karnovsky. PNAS May 1990; 87: 3773-3777. 

(2) Perivascular and intravenous administration of basic fibroblast growth factor: Vascular and solid organ deposition. ER Edelman, MA Nugent, and MJ Karnovsky. PNAS Feb 1993; 90: 1513-1517. 

(3) Tissue concentration of heparin, not administered dose, correlates with the biological response of injured arteries in vivo. MA Lovich and ER Edelman. PNAS Sep 1999; 96: 11111–11116.

Vascular Injury and Repair

Perlecan is a heparin-sulfate proteoglycan that might be critical for regulation of vascular repair by inhibiting the binding and mitogenic activity of basic fibroblast growth factor-2 (bFGF-2) in vascular smooth muscle cells .

The Team generated

Clones of endothelial cells expressing an antisense vector targeting domain III of perlecan. The transfected cells produced significantly less perlecan than parent cells, and they had reduced bFGF in vascular smooth muscle cells.
Endothelial cells were seeded onto three-dimensional polymeric matrices and implanted adjacent to porcine carotid arteries subjected to deep injury.
The parent endothelial cells prevented thrombosis, but perlecan deficient cells were ineffective.

The ability of endothelial cells to inhibit intimal hyperplasia, however, was only in part suppressed by perlecan. The differential regulation by perlecan of these aspects of vascular repair may clarify why control of clinical clot formation does not lead to full control of intimal hyperplasia.

The use of genetically modified tissue engineered cells provides a new approach for dissecting the role of specific factors within the blood vessel wall.(1) Successful implementation of local arterial drug delivery requires transmural distribution of drug. The physicochemical properties of the applied compound govern its transport and tissue binding.

Hydrophilic compounds are cleared rapidly.
Hydrophobic drugs bind to fixed tissue elements, potentially prolonging tissue residence and biological effect.

Local vascular drug delivery provides

elevated concentrations of drug in the target tissue while
minimizing systemic side effects.

To better characterize local pharmacokinetics the Team examined the arterial transport of locally applied dextran and dextran derivatives in vivo.

Using a two-compartment pharmacokinetic model to correct

The measured transmural flux of these compounds for systemic
Redistribution and elimination as delivered from a photo-polymerizable hydrogel.
The diffusivities and the transendothelial permeabilities were strongly dependent on molecular weight and charge
For neutral dextrans, the diffusive resistance increased with molecular weightapproximately 4.1-fold between the molecular weights of 10 and 282 kDa.
Endothelial resistance increased 28-fold over the same molecular weight range.
The effective medial diffusive resistance was unaffected by cationic charge as such molecules moved identically to neutral compounds, but increased approximately 40% when dextrans were negatively charged.

Transendothelial resistance was 20-fold lower for the cationic dextrans, and 11-fold higher for the anionic dextrans, when both were compared to neutral counterparts.

These results suggest that, while

low molecular weight drugs will rapidly traverse the arterial wall with the endothelium posing a minimal barrier,

the reverse is true for high molecular weight agents.

The deposition and distribution of locally released vascular therapeutic compounds might be predicted based upon chemical properties, such as molecular weight and charge. (2)

Paclitaxel is hydrophobic and has therapeutic potential against proliferative vascular disease.  The favorable preclinical data with this compound may, in part, result from preferential tissue binding.  The complexity of Paclitaxel pharmacokinetics required in-depth investigation if this drug is to reach its full clinical potential in proliferative vascular diseases.

Equilibrium distribution of Paclitaxel reveals partitioning above and beyond perfusate concentration and a spatial gradient of drug across the arterial wall.

The effective diffusivity (Deff) was estimated from the Paclitaxel distribution data to

facilitate comparison of transport of Paclitaxel through arterial parenchyma with that of other vasoactive agents and to
characterize the disparity between endovascular and perivascular application of drug.

This transport parameter described the motion of drug in tissues given an applied concentration gradient and includes, in addition to diffusion,

the impact of steric hindrance within the arterial interstitium;
nonspecific binding to arterial elements; and, in the preparation used here,
convective effects from the applied transmural pressure gradient.

At all times, the effective diffusivity for endovascular delivery exceeded that of perivascular delivery. The arterial transport of Paclitaxel was quantified through application ex vivo and measurement of the subsequent transmural distribution.

Arterial Paclitaxel deposition at equilibrium varied across the arterial wall.
Permeation into the wall increased with time, from 15 minutes to 4 hours, and
varied with the origin of delivery.

In contrast to hydrophilic compounds, the concentration in tissue exceeded the applied concentration and the rate of transport was markedly slower. Furthermore, endovascular and perivascular Paclitaxel application led to differences in deposition across the blood vessel wall.

This leads to a conclusion that Paclitaxel interacts with arterial tissue elements as it moves under the forces of

diffusion and
convection and
can establish substantial partitioning and spatial gradients across the tissue. (3)

Endovascular drug-eluting stents have changed the practice of cardiovascular vascularization, and yet it is unclear how they so dramatically reduce restenosis

We don’t know how to distinguish between the different formulations available.  Researchers are now questioning whether individual properties of different drugs beyond lipid avidity effect arterial transport and distribution.

In bovine internal carotid segments, tissue-loading profiles for

Hydrophobic Paclitaxel and Rapamycin are indistinguishable, reaching load steady state after 2 days.
Hydrophilic dextran reaches equilibrium in hours.

Paclitaxel and Rapamycin bind to the artery at 30–40 times bulk concentration, and bind to specific tissue elements.

Transmural drug distribution profiles are markedly different for the two compounds.

Rapamycin binds specifically to FKBP12 binding protein and it distributes evenly through the artery,
Paclitaxel binds specifically to microtubules, and remains primarily in the subintimal space.

The binding of Rapamycin and Paclitaxel to specific intracellular proteins plays an essential role in

determining arterial transport and distribution and in
distinguishing one compound from another.

These results offer further insight into the

mechanism of local drug delivery and the
specific use of existing drug-eluting stent formulations. (4)

The Role of Amyloid beta (A) in Creation of Vascular Toxic Plaque

Amyloid beta (A) is a peptide family produced and deposited in neurons and endothelial cells (EC). It is found at subnanomolar concentrations in the plasma of healthy individuals.  Simple conformational changes produce a form of A-beta , A-beta 42, which creates toxic plaque in the brains of Alzheimer’s patients.

Oxidative stress induced blood brain barrier degeneration has been proposed as a key factor for A-beta 42 toxicity.

This cannot account for lack of injury from the same peptide in healthy tissues. Researchers hypothesized that cell state mediates A-beta’s effect.  They examined the viability in the presence of A-beta secreted from transfected Chinese hamster ovary cells (CHO) of

aortic Endothelial Cells (EC),
vascular smooth muscle cells (SMC) and
epithelial cells (EPI) in different states

A-beta was more toxic to all cell types when they were subconfluent.  Subconfluent EC sprouted and SMC and EPI were inhibited by A-beta. Confluent EC were virtually resistant to A-beta and suppressed A-beta production by A-beta +CHO.

Products of subconfluent EC overcame this resistant state, stimulating the production and toxicity of A-beta 42. Confluent EC overgrew >35% beyond their quiescent state in the presence of A-beta conditioned in media from subconfluent EC.

These findings imply that A-beta 42 may well be even more cytotoxic to cells in injured or growth states and potentially explain the variable and potent effects of this protein.

One may now need to consider tissue and cell state in addition to local concentration of and exposure duration to A-beta.

The specific interactions of A-beta and EC in a state-dependent fashion may help understand further the common and divergent forms of vascular and cerebral toxicity of A-beta and the spectrum of AD. (5)

(1) Perlecan is required to inhibit thrombosis after deep vascular injury and contributes to endothelial cell-mediated inhibition of intimal hyperplasia. MA Nugent, HM Nugent, RV Iozzoi, K Sanchack, and ER Edelman. PNAS Jun 2000; 97(12): 6722-6727 

(2) Correlation of transarterial transport of various dextrans with their physicochemical properties. O Elmalak, MA Lovich, E Edelman. Biomaterials 2000; 21: 2263-2272 

(3) Arterial Paclitaxel Distribution and Deposition. CJ Creel, MA Lovich, ER Edelman. Circ Res. 2000;86:879-884 

(4) Specific binding to intracellular proteins determines arterial transport properties for rapamycin and Paclitaxel. AD Levin, N Vukmirovic, Chao-Wei Hwang, and ER Edelman. PNAS Jun 2004; 101(25): 9463–9467. www.pnas.org/cgi/doi/10.1073/pnas.0400918101 

(5) Amyloid beta toxicity dependent upon endothelial cell state. M Balcells, JS Wallins, ER Edelman. Neuroscience Letters 441 (2008) 319–322

Endothelial Damage as an Inflammatory State

Autoimmunity may drive vascular disease through anti-endothelial cell (EC) antibodies. This raises a question about whether an increased morbidity of cardiovascular diseases in concert with systemic illnesses may involve these antibodies.

Matrix-embedded ECs act as powerful regulators of vascular repair accompanied by significant reduction in expected systemic and local inflammation.

The Lab researchers compared the immune response against free and matrix-embedded ECs in naive mice and mice with heightened EC immune reactivity. Mice were presensitized to EC with repeated subcutaneous injections of saline-suspended porcine EC (PAE) (5*10^5 cells).

On day 42, both naive mice (controls) and mice with heightened EC immune reactivity received 5*10^5 matrix-embedded or free PAEs. Circulating PAE-specific antibodies and effector T-cells were analyzed 90 days after implantation for –

PAE-specific antibody-titers,
frequency of CD4+-effector cells, and
xenoreactive splenocytes

These were 2- to 4-fold lower (P<0.0001) when naıve mice were injected with matrix-embedded instead of saline-suspended PAEs.

Though basal levels of circulating antibodies were significantly elevated after serial PAE injections (2210+341 mean fluorescence intensity, day 42) and almost doubled again 90 days after injection of a fourth set of free PAEs, antibody levels declined by half in recipients of matrix-embedded PAEs at day 42 (P<0.0001), as did levels of CD4+-effector cells and xenoreactive splenocytes.

A significant immune response to implantation of free PAE is elicited in naıve mice, that is even more pronounced in mice with pre-developed anti-endothelial immunity.

Matrix-embedding protects xenogeneic ECs against immune reaction in naive mice and in mice with heightened immune reactivity.

Matrix-embedded EC might offer a promising approach for treatment of advanced cardiovascular disease. (1)

Researchers examined the molecular mechanisms through which

mechanical force and hypertension modulate

endothelial cell regulation of vascular homeostasis.

Exposure to mechanical strain increased the paracrine inhibition of vascular smooth muscle cells (VSMCs) by endothelial cells.

Mechanical strain stimulated the production by endothelial cells of perlecan and heparan-sulfate glycosaminoglycans. By inhibiting the expression of perlecan with an antisense vector researchers demonstrated that perlecan was essential to the strain-mediated effects on endothelial cell growth control.

Mechanical regulation of perlecan expression in endothelial cells was

governed by a mechano-transduction pathway
requiring transforming growth factor (TGF-β) signaling and
intracellular signaling through the ERK pathway.

Immunohistochemical staining of the aortae of spontaneously hypertensive rats demonstrated strong correlations between

endothelial TGF-β,
phosphorylated signaling intermediates, and
arterial thickening.

Studies on ex vivo arteries exposed to varying levels of pressure demonstrated that

ERK and TGF-beta signaling were required for pressure-induced upregulation of endothelial HSPG.

The Team’s findings suggest a novel feedback control mechanism in which

net arterial remodeling to hemodynamic forces is controlled by a dynamic interplay between growth stimulatory signals from vSMCs and
growth inhibitory signals from endothelial cells. (2)

Heparan-sulfate proteoglycans (HSPGs) are potent regulators of vascular remodeling and repair.  The major enzyme capable of degrading HSPGs is heparanase, which led us to examine the role of heparanase in controlling

arterial structure,
mechanics, and
remodeling.

In vitro studies suggested heparanase expression in endothelial cells serves as a negative regulator of endothelial inhibition of vascular smooth muscle cell (vSMC) proliferation.

ECs inhibit vSMC proliferation through the interplay between

growth stimulatory signals from vSMCs and
growth inhibitory signals from ECs.

This would be expected if ECs had HSPGs that are degraded by heparanase. Arterial structure and remodeling to injury is modified by heparanase expression. Transgenic mice overexpressing heparanase had

increased arterial thickness,
cellular density, and
mechanical compliance.

Endovascular stenting studies in Zucker rats demonstrated increased heparanase expression in the neointima of obese, hyperlipidemic rats in comparison to lean rats.

The extent of heparanase expression within the neointima strongly correlated with the neointimal thickness following injury. To test the effects of heparanase overexpression on arterial repair, researchers developed a novel murine model of stent injury using small diameter self-expanding stents.

Using this model, researchers found that increased

neointimal formation and
macrophage recruitment occurs in transgenic mice overexpressing heparanase.
Taken together, these results support a role for heparanase in the regulation of arterial structure, mechanics, and repair. (3)

The first host–donor reaction in transplantation occurs at the blood–tissue interface. When the primary component of the implant (donor) is the endothelial cells, it incites an immunologic reaction. Injections of free endothelial cell implants elicit a profound major histocompatibility complex (MHC) II dominated immune response.

Endothelial cells embedded within three-dimensional matrices behave like quiescent endothelial cells.

Perivascular implants of such embedded ECs cells are the most potent inhibitor of intimal hyperplasia and thrombosis following controlled vascular injury, but without any immune reactivity.

Allo- and even exenogenic endothelial cells evoke no significant humoral or cellular immune response in immune-competent hosts when embedded within matrices.  Moreover, endothelial implants are immune-modulatory, reducing the extent of the memory response to previous free cell implants.

Attenuated immunogenicity results in muted activation of adaptive and innate immune cells. These findings point toward a pivotal role of matrix–cell-interconnectivity for

the cellular immune phenotype and might therefore assist in the design of
extracellular matrix components for successful tissue engineering. (4)

Because changes in subendothelial matrix composition are associated with alterations of the endothelial immune phenotype, researchers sought to understand if

cytokine-induced NF-κB activity and
downstream effects depend on substrate adherence of endothelial cells (EC).

The team compared the upstream

phosphorylation cascade,
activation of NF-ĸβ, and
expression/secretion

of downstream effects of EC grown on tissue culture polystyrene plates (TCPS) with EC embedded within collagen-based matrices (MEEC).

Adhesion of natural killer (NK) cells was quantified in vitro and in vivo.

NF-κβ subunit p65 nuclear levels were significantly lower and
p50 significantly higher in cytokine-stimulated MEEC than in EC-TCPS.

Despite similar surface expression of TNF-α receptors, MEEC had significantly decreased secretion and expression of IL-6, IL-8, MCP-1, VCAM-1, and ICAM-1.

Attenuated fractalkine expression and secretion in MEEC (two to threefold lower than in EC-TCPS; p < 0.0002) correlated with 3.7-fold lower NK cell adhesion to EC (6,335 ± 420 vs. 1,735 ± 135 cpm; p < 0.0002).

Furthermore, NK cell infiltration into sites of EC implantation in vivo was significantly reduced when EC were embedded within matrix.

Matrix embedding enables control of EC substratum interaction.

This in turn regulates chemokine and surface molecule expression and secretion, in particular – of those compounds within NF-κβ pathways,

chemoattraction of NK cells,
local inflammation, and
tissue repair. (5)

Monocyte recruitment and interaction with the endothelium is imperative to vascular recovery.

Tie2 plays a key role in endothelial health and vascular remodeling. Researchers studied monocyte-mediated Tie2/angiopoietin signaling following interaction of primary monocytes with endothelial cells and its role in endothelial cell survival.

The direct interaction of primary monocytes with subconfluent endothelial cells

resulted in transient secretion of angiopoietin-1 from monocytes and

the activation of endothelial Tie2. This effect was abolished by preactivation of monocytes with tumor necrosis factor-α (TNFα).

Although primary monocytes contained high levels of

both angiopoietin 1 and 2,
endothelial cells contained primarily angiopoietin 2.

Seeding of monocytes on serum-starved endothelial cells reduced caspase-3 activity by 46+5.1%, and 52+5.8% after TNFα treatment, and it decreased single-stranded DNA levels by 41+4.2% and 40+ 3.5%, respectively.

This protective effect of monocytes on endothelial cells was reversed by Tie2 silencing with specific short interfering RNA.

The antiapoptotic effect of monocytes was further supported by the

activation of cell survival signaling pathways involving phosphatidylinositol 3-kinase,
STAT3, and
AKT.

Monocytes and endothelial cells form a unique Tie2/angiopoietin-1 signaling system that affects endothelial cell survival and may play critical a role in vascular remodeling and homeostasis. (6)

(1) Cell–Matrix Contact Prevents Recognition and Damage of Endothelial Cells in States of Heightened Immunity. H Methe, ER Edelman. Circulation. 2006;114[suppl I]:I-233–I-238. http://www.circulationaha.org/DOI/10.1161/CIRCULATIONAHA.105.000687

(2) Endothelial Cells Provide Feedback Control for Vascular Remodeling Through a Mechanosensitive Autocrine TGFβ Signaling Pathway. AB Baker, DS Ettenson, M Jonas, MA Nugent, RV Iozzo, ER Edelman. Circ. Res. 2008;103;289-297 http://dx.doi.org/10.1161/CIRCRESAHA.108.179465 http://circres.ahajournals.org/cgi/content/full/103/3/289

(3) Heparanase Alters Arterial Structure, Mechanics, and Repair Following Endovascular Stenting in Mice. AB Baker, A Groothuis, M Jonas, DS Ettenson…ER Edelman. Circ. Res. 2009;104;380-387; http://dx.doi.org/10.1161/CIRCRESAHA.108.180695 http://circres.ahajournals.org/cgi/content/full/104/3/380

(4) The effect of three-dimensional matrix-embedding of endothelial cells on the humoral and cellular immune response. H Methe, S Hess, ER Edelman. Seminars in Immunology 20 (2008) 117–122. http://dx.doi.org/10.1016/j.smim.2007.12.005

(5) NF-kB Activity in Endothelial Cells Is Modulated by Cell Substratum Inter-actions and Influences Chemokine-Mediated Adhesion of Natural Killer Cells. S Hess, H Methe, Jong-Oh Kim, ER Edelman. Cell Transplantation 2009; 18: 261–273 

(6) Primary Monocytes Regulate Endothelial Cell Survival Through Secretion of Angiopoietin-1 and Activation of Endothelial Tie2. SY Schubert, A Benarroch, J Monter-Solans and ER Edelman. Arterioscler Thromb Vasc Biol 2011;31;870-875 http://dx.doi.org/10.1161/ATVBAHA.110.218255

Neointimal Formation, Shear Stress, and Remodelling with Reference to Diabetes

Innate immunity is of major importance in vascular repair. The present study evaluated whether

systemic and transient depletion of monocytes and macrophages with
liposome-encapsulated bisphosphonates inhibits experimental in-stent neointimal formation.

The Experiment

Rabbits fed on a hypercholesterolemic diet underwent bilateral iliac artery balloon denudation and stent deployment.

Liposomal alendronate (3 or 6 mg/kg) was given concurrently with stenting.

Monocyte counts were reduced by 90% 24 to 48 hours aftera single injection of liposomal alendronate, returning to basal levels at 6 days.

This treatment significantly reduced

intimal area at 28 days, from 3.88+0.93 to 2.08+0.58 and 2.16 +0.62 mm2.
Lumen area was increased from 2.87+0.44 to 3.57+0.65 and 3.45+0.58 mm2, and

arterial stenosis was reduced from 58 11% to 37 8% and 38 7% in controls, in rabbits treated with 3 mg/kg, and with 6 mg/kg, respectively (mean+SD, n=8 rabbits/group, P< 0.01 for all 3 parameters).

No drug-related adverse effects were observed. Reduction in neointimal formation was associated with

reduced arterial macrophage infiltration and proliferation at 6 days and with an
equal reduction in intimal macrophage and smooth muscle cell content at 28 days after injury.

Conversely, drug regimens ineffective in reducing monocyte levels did not inhibit neointimal formation. Researchers have shown that a

single liposomal bisphosphonates injection concurrent with injury reduces in-stent neointimal formation and
arterial stenosis in hypercholesterolemic rabbits, accompanied by systemic transient depletion of monocytes and macrophages. (1)

Diabetes and insulin resistance are associated with increased disease risk and poor outcomes from cardiovascular interventions.

Even drug-eluting stents exhibit reduced efficacy in patients with diabetes. Researchers reported the first study of vascular response to stent injury in insulin-resistant and diabetic animal models.

Endovascular stents were expanded in the aortae of

obese insulin-resistant and
type 2 diabetic Zucker rats,
in streptozotocin-induced type 1 diabetic Sprague-Dawley rats, and
in matched controls.

Insulin-resistant rats developed thicker neointima (0.46+0.08 versus 0.37+0.06 mm2, P 0.05), with decreased lumen area (2.95+0.26 versus 3.29+0.15 mm2, P 0.03) 14 days after stenting compared with controls, but without increased vascular inflammation (tissue macrophages).

Insulin-resistant and diabetic rat vessels did exhibit markedly altered signaling pathway activation 1 and 2 weeks after stenting, with up to a 98% increase in p-ERK (anti-phospho ERK) and a 54% reduction in p-Akt (anti-phospho Akt) stained cells. Western blotting confirmed a profound effect of insulin resistance and diabetes on Akt and ERK signaling in stented segments. p-ERK/p-Akt ratio in stented segments uniquely correlated with neointimal response (R2 = 0.888, P< 0.04) , but not in lean controls.

Transfemoral aortic stenting in rats provides insight into vascular responses in insulin resistance and diabetes.

Shifts in ERK and Akt signaling related to insulin resistance may reflect altered tissue repair in diabetes accompanied by a

shift in metabolic : proliferative balance.

These findings may help explain the increased vascular morbidity in diabetes and suggest specific therapies for patients with insulin resistance and diabetes. (2)

Researchers investigated the role of Valsartan (V) alone or in combination with Simvastatin (S) on coronary atherosclerosis and vascular remodeling, and tested the hypothesis that V or V/S attenuate the pro-inflammatory effect of low endothelial shear stress (ESS).

Twenty-four diabetic, hyperlipidemic swine were allocated into Early (n = 12) and Late (n=12) groups. Diabetic swine in each group were treated with Placebo (n=4), V (n = 4) and V/S (n = 4) and followed for 8 weeks in the Early group and 30 weeks in the Late group.

Blood pressure, serum cholesterol and glucose were similar across the treatment subgroups. ESS was calculated in plaque-free subsegments of interest (n = 109) in the Late group at week 23. Coronary arteries of this group were harvested at week 30, and the subsegments of interest were identified, and analyzed histopathologically.

Intravascular geometrically correct 3-dimensional reconstruction of the coronary arteries of 12 swine was performed 23 weeks after initiation of diabetes mellitus and a hyperlipidemic diet. Local endothelial shear stress was calculated

in plaque-free subsegments of interest (n=142) with computational fluid dynamics, and
the coronary arteries (n=31) were harvested and the same subsegments were identified at 30 weeks.

V alone or with S

reduced the severity of inflammation in high-risk plaques. Both regimens attenuated the severity of enzymatic degradation of the arterial wall, reducing the severity of expansive remodeling.
attenuated the pro-inflammatory effect of low ESS. V alone or with S
exerts a beneficial effect of reducing and stabilizing high-risk plaque characteristics independent of a blood pressure- and lipid-lowering effect. (3)

This study tested the hypothesis that low endothelial shear stress augments the

expression of matrix-degrading proteases, promoting the
formation of thin-capped atheromata.

Researchers assessed the messenger RNA and protein expression, and elastolytic activity of selected elastases and their endogenous inhibitors.

Subsegments with low endothelial shear stress at week 23 showed

reduced endothelial coverage,
enhanced lipid accumulation, and
intense infiltration of activated inflammatory cells at week 30.

These lesions showed increased expression of messenger RNAs encoding

matrix metalloproteinase-2, -9, and -12, and cathepsins K and S
relative to their endogenous inhibitors and
increased elastolytic activity.

Expression of these enzymes correlated positively with the severity of internal elastic lamina fragmentation.

Thin-capped atheromata in regions with

lower preceding endothelial shear stress had
reduced endothelial coverage,
intense lipid and inflammatory cell accumulation,
enhanced messenger RNA expression and
elastolytic activity of MMPs and cathepsins with
severe internal elastic lamina fragmentation.

Low endothelial shear stress induces endothelial discontinuity and

accumulation of activated inflammatory cells, thereby
augmenting the expression and activity of elastases in the intima and
shifting the balance with their inhibitors toward matrix breakdown.

Team’s results provide new insight into the mechanisms of regional formation of plaques with thin fibrous caps. (4)

Elevated CRP levels predict increased incidence of cardiovascular events and poor outcomes following interventions. There is the suggestion that CRP is also a mediator of vascular injury.

Transgenic mice carrying the human CRP gene (CRPtg) are predisposed to arterial thrombosis post-injury.

Researchers examined whether CRP similarly modulates the proliferative and hyperplastic phases of vascular repair in CRPtg when thrombosis is controlled with daily aspirin and heparin at the time of trans-femoral arterial wire-injury.

Complete thrombotic arterial occlusion at 28 days was comparable for wild-type and CRPtg mice (14 and 19%, respectively). Neointimal area at 28d was 2.5 fold lower in CRPtg (4190±3134 m2, n = 12) compared to wild-types (10,157±8890 m2, n = 11, p < 0.05).

Likewise, neointimal/media area ratio was 1.10±0.87 in wild-types and 0.45±0.24 in CRPtg (p < 0.05).

Seven days post-injury, cellular proliferation and apoptotic cell number in the intima were both less pronounced in CRPtg than wild-type.
No differences were seen in leukocyte infiltration or endothelial coverage. CRPtg mice had significantly reduced p38 MAPK signaling pathway activation following injury.

The pro-thrombotic phenotype of CRPtg mice was suppressed by aspirin/heparin, revealing CRP’s influence on neointimal growth after trans-femoral arterial wire-injury.

Signaling pathway activation,
cellular proliferation, and
neointimal formation

were all reduced in CRPtg following vascular injury.  Increasingly the Team was aware of CRP multipotent effects.  Once considered only a risk factor, and recently a harmful agent, CRP is a far more complex regulator of vascular biology. (5)

(1) Liposomal Alendronate Inhibits Systemic Innate Immunity and Reduces In-Stent Neointimal Hyperplasia in Rabbits. HD Danenberg, G Golomb, A Groothuis, J Gao…, ER Edelman. Circulation. 2003;108:2798-2804 

(2) Vascular Neointimal Formation and Signaling Pathway Activation in Response to Stent Injury in Insulin-Resistant and Diabetic Animals. M Jonas, ER Edelman, A Groothuis, AB Baker, P Seifert, C Rogers. Circ. Res. 2005;97;725-733. http://dx.doi.org/10.1161/01.RES.0000183730.52908.C6 http://circres.ahajournals.org/cgi/content/full/97/7/725

(3) Attenuation of inflammation and expansive remodeling by Valsartan alone or in combination with Simvastatin in high-risk coronary atherosclerotic plaques. YS Chatzizisis, M Jonas, R Beigel, AU Coskun… ER Edelman, CL Feldman, PH Stone. Atherosclerosis 203 (2009) 387–394 

(4) Augmented Expression and Activity of Extracellular Matrix-Degrading Enzymes in Regions of Low Endothelial Shear Stress Colocalize With Coronary Atheromata With Thin Fibrous Caps in Pigs. YS Chatzizisis, AB Baker, GK Sukhova,…P Libby, CL Feldman, ER Edelman, PH Stone Circulation 2011;123;621-630 http://dx.doi.org/10.1161/CIRCULATIONAHA.110.970038 http://circ.ahajournals.org/cgi/content/full/123/6/621 

(5) Neointimal formation is reduced after arterial injury in human crp transgenic mice HD Danenberg, E Grad, RV Swaminathan, Z Chenc,…ER Edelman Atherosclerosis 201 (2008) 85–91

A Rattle Bag of Science and the Art of Translation

Science Translational Medicine – A rattle bag of science and the art of translation E. R. Edelman, G. A. FitzGerald. Sci.Transl. Med. 3, 104ed3 (2011). http://dx.doi.org/10.1126/scitranslmed.3002131

Elazer R. Edelman is the Thomas D. and Virginia W. Cabot Professor of Health Sciences and Technology at MIT, Professor of Medicine at Harvard Medical School, a coronary care unit cardiologist at the Brigham and Women’s Hospital, and Director of the Harvard-MIT Biomedical Engineering Center. E-mail: ere@mit.edu

Garret A. FitzGerald is the McNeil Professor in Translational Medicine and Therapeutics, Chair of the Department of Pharmacology, and Director of the Institute for Translational Medicine & Therapeutics, University of Pennsylvania. E-mail: garret@upenn.edu

In 2011, the American Association for the Advancement of Science (AAAS) founded Science Translational Medicine (STM) to disseminate interdisciplinary science integrating basic and clinical research that defines and fosters new therapeutics, devices, and diagnostics.

Conceived and nourished under the creative vision of Elias Zerhouni and Katrina Kelner, the journal has attracted widespread attention. Now, as we assume the mantle of co-chief scientific advisors, we look back on the journal’s early accomplishments, restate our mission, and make clear the kinds of manuscripts we seek and accept for publication.

STM’s mission, as articulated by Elias and Katrina, was to

“promote human health by providing a forum for communication and cross-fertilization among basic, translational, and clinical research practitioners and trainees from all relevant established and emerging disciplines.”

This statement remains relevant and accurate today.  With this mission on our masthead, STM now receives ~25 manuscripts (full-length research articles) per week and publishes ~10% of them. Roughly half of the submissions are deemed inappropriate for the journal and are returned without review within 8 to 10 days of receipt.

Of those papers that undergo full peer review,

decisions to reject are made within 48 days and

the mean time to acceptance (including the revision period) is 125 days.

There is now an average wait of only 24 days between acceptance and publication.

Defining TRANSLATIONAL Medicine

In accord with the journal’s broad readership, the ideal manuscript meets five criteria: It (i) reports a discovery of translational relevance with high-impact potential; (ii) has a conceptual focus with interdisciplinary appeal; (iii) elucidates a biological mechanism; (iv) is innovative and novel; and (v) is presented in clear, broadly accessible language.  STM seeks to publish research that describes

how innovative concepts drive the creative biomedical science
that ultimately improves the quality of people’s lives—

This is the broadest of our journal’s criteria but is the one that sets us apart as well. Translational relevance does not require demonstration of benefit in humans but does require the evident potential to advance clinical medicine, thus impacting the direction of our culture and the welfare of our communities. Conceptual focus and mechanistic emphasis discriminate our papers from those that contain observational descriptions of technical findings for which value is restricted to a specific discipline.

However, innovation and novelty may apply to a fundamental scientific discovery or to the nature of its application and relevance to the translational process. Criteria enable the journal to consider versatile technological advances that apply new and creative thinking but may not necessarily offer fresh insights into biological mechanisms. Finally, while the subsequent additional efforts of the STM editorial staff are not to be discounted, the clarity of writing and coherence of argument presented within a submitted manuscript are likely to facilitate its progress through the challenge of peer review.

On Causes – Hippocrates, Aristotle, Robert Koch, and the Dread Pirate Roberts

Elazer R. Edelman Circulation 2001;104:2509-2512

The idea of risk factors for vascular disease has evolved

from a dichotomous to continuous hazard analysis and
from the consideration of a few factors to
mechanistic investigation of many interrelated risks.

However, confusion still abounds regarding issues of association and causation. Originally, the simple presence of

tobacco abuse, hypertension, and/or hypercholesterolemia were tallied, and
the cumulative score was predictive of subsequent coronary artery disease.

Since then, dose responses have been defined for these and other factors and it has been suggested that almost 300 factors place patients at risk; these factors include elevations in plasma homocysteine.  Recent studies shed interesting light on the mechanism of this potentially causal relationship, which was first noted in 1969.

Aside from putative effects on vessel wall dynamics, there is now direct evidence that homocysteine is atherogenic. Twenty-fold increases in plasma homocysteine achieved by dietary manipulation of apoE–/– mice increased aortic root lesion size 2-fold and produced a prolonged chronic inflammatory mural response accompanied by elevations in vascular cell adhesion molecule-1 (VCAM) and tumor necrosis factor-a (TNF-a).

In long term followup, homocysteine levels elevated by

dietary supplementation with methionine or homocysteine
promoted lesion size and plaque fibrosis in these
atherosclerosis-prone mice early in life, but without influencing ultimate plaque burden as the animals aged.

A number of mechanisms were proposed by which homocysteine achieved this effect, including

promotion of inflammation,
regulation of lipoprotein metabolism, and
modification of critical biochemical pathways and
metabolites including nitric oxide (NO).

See p 2569 In the present issue of Circulation,

Stühlinger et al 7 advance these mechanistic insights one critical step further by defining homocysteine’s effects at an enzymatic level.

The group led by Lentz published an association between levels of the

endogenous inhibitor of Nirtic Oxide synthase,
asymmetric dimethyl arginine (ADMA), and

homocysteine in cultured endothelial cells and in the serum of cynomolgus monkeys.

Such an association is interesting because the L-arginine–NO synthase pathway seems to be a critical component in the full range of endothelial cell biology and vascular dysfunction.

Stühlinger et al 7 now show that increased cultured endothelial cell elaboration of ADMA by homocysteine and its precursor L-methionine is associated with a dose-dependent impairment of the activity of endothelial dimethylarginine dimethylaminohydrolase (DDAH), the enzyme that degrades ADMA. Homocysteine directly inhibited DDAH activity in a cell-free system by targeting a critical sulfhydryl group on this enzyme.

Thus, one could envision that the balance of cardiovascular health and disease could well be determined by the ability of an intact Nirtic Oxide synthase system to overcome environmental, dietary, and even genetic factors.

In patients with altered enzymatic defense systems,

elevated homocysteine,
oxidized lipoproteins,
inflammation, and other
vasotoxins

may dominate even the most potent defense mechanisms. These studies raise a number of issues. Do we need to add to our list of established cardiovascular risk factors to accommodate new findings and associations? Is there a final common pathway for all risk factors or perhaps even a unified factor theory into which all potential risks can be grouped? And, as always, should we consider Nirtic Oxide at the core of this universality? Finally, should we change our focus altogether and speak not of risk factors but of

genetic predisposition,
extent of biochemical aberration, and
degree of physical damage?

Some would view these remarkable success stories and the repeated association of hyperhomocyst(e)inemia with coronary, cerebral, and peripheral vascular disease and simply advocate for increased folic acid intake for all.

Indeed, this intervention of negligible cost and

insignificant side effect is already partially in place;
many foods are fortified with folate to prevent congenital neural tube defects.

This reader considers the seminal work by Vernon Young and Yves Ingenbleek on the relationship between

S8 and regions distant from lava flows in Asia and Indian subcontinents,
where they have determined hyperhomocysteinemia and the consequence associated with:
veganism (not voluntary)
impaired methyl donor reactions and transsulfuration pathways (not corrected by B12, folate)
loss of lean body mass due to the constant relationship of S:N (insufficient from plant sources)

What happens, when we fail to continue to pursue causality,

the linkage of biological significance or scientific plausibility with
epidemiologically or statistically significant association?

In medicine, risk becomes the likelihood that people without a disease will acquire the disease through contact with factors thought to increase disease risk.

All of these risk factors are then, by nature, imprecise and nonspecific.  They are stochastic measures of what will happen to normal people who fall into particular measures of these parameters.

The daring may be willing to accept these risks, citing friend and foe who live well beyond or for far lesser times than anticipated by risk alone. Such concerns may well become moot if we can simultaneously identify patients at risk

by linking phenotype with genotype,
gene expression with protein elaboration, and
environmental exposures with the biochemical consequences and
direct anatomic aberrations they induce.

This kind of characterization may well replace a family history of arterial disease as a rough estimate of

genotype,

serum cholesterol as an indirect measure of the health of lipoprotein metabolism,
serum glucose as a crude determinant of the ravages of diabetes mellitus,
blood pressure measurement as a marker of long-standing endogenous exposure to altered flow, and
tobacco abuse as a maker of long-standing exposure to exogenous toxins.

Rather than identifying patients on the basis of their serum cholesterol, we will have a direct measure of their

LDL receptor number,
internalization rate,
macrophage content in the blood vessel wall,
metalloproteinase activity, etc.
insulin receptor metabolism,
oxidative state, and
glycated burden.
Serum glucose will similarly give way to these tests

Evaluating a new way to open clogged arteries: Computational model offers insight into mechanisms of drug-coated balloons.

A new study from MIT analyzes the potential usefulness of a new treatment that combines the benefits of angioplasty balloons and drug-releasing stents, but may pose fewer risks. With this new approach, a balloon is inflated in the artery for only a brief period, during which it releases a drug that prevents cells from accumulating and clogging the arteries over time.

While approved for limited use in Europe, these drug-coated balloons are still in development in the United States and have not received FDA approval. The MIT study, which models the behavior of the balloons, should help scientists optimize their performance and aid regulators in evaluating their effectiveness and safety.

“Until now, people who evaluate such technology could not distinguish hype from promise,” says Elazer Edelman, the Thomas D. and Virginia W. Cabot Professor of Health Sciences and Technology and senior author of the paper describing the study, which appeared online recently in the journal Circulation.

Lead author of the paper is Vijaya Kolachalama, a former MIT postdoc who is now a principal member of the technical staff at the Charles Stark Draper Laboratory.

Edelman’s lab is investigating a possible alternative to the current treatments: drug-coated balloons. “We’re trying to understand how and when this therapy could work and identify the conditions in which it may not,” Kolachalama says. “It has its merits; it has some disadvantages.”

Modeling drug release

The drug-coated balloons are delivered by a catheter and inflated at the narrowed artery for about 30 seconds, sometimes longer. During that time, the balloon coating, containing a drug such as Zotarolimus, is released from the balloon. The properties of the coating allow the drug to be absorbed in the body’s tissues. Once the drug is released, the balloon is removed.

In their new study, Kolachalama, Edelman and colleagues set out to rigorously characterize the properties of the drug-coated balloons. After performing experiments in tissue grown in the lab and in pigs, they developed a computer model that explains the dynamics of drug release and distribution. They found that factors such as the size of the balloon, the duration of delivery time, and the composition of the drug coating all influence how long the drug stays at the injury site and how effectively it clears the arteries.

One significant finding is that when the drug is released, some of it sticks to the lining of the blood vessels. Over time, that drug is slowly released back into the tissue, which explains why the drug’s effects last much longer than the initial 30-second release period.

“This is the first time we can explain the reasons why drug-coated balloons can work,” Kolachalama says. “The study also offers areas where people can consider thinking about optimizing drug transfer and delivery.”

http://circ.ahajournals.org/content/127/20/2047.short
http://www.mit.edu/people/vbk/Circulation_2013.pdf
http://www.sciencedaily.com/…13/05/130521121513.ht…
Circulation, 2013; 127 (20): 2047 – 2055
http://dx.doi.org/10.1161/CIRCULATIONAHA.113.002051;

Conclusion

MIT’s Edelman’s Lab conducted the pioneering work in Vascular biology, animal models of drug eluting stents and was at the forefront of Empirical Molecular Cardiology in its studies in vascular physiology, biology and biomaterials for medical devices.

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The Heart Revolution By Kilmer McCully, Martha McCully

HarperCollinsPublishers, 1969

http://books.google.com/books?id=iYLbuZFxEt8C&pg=PR20&dq=New+York+Times+homocysteine+and+Cholesterol&hl=en&sa=X&ei=_0F7UfDRA8zB4APozIHQAQ&ved=0CEMQ6AEwAg

Paclitaxel: Pharmacokinetic (PK), Pharmacodynamic (PD) and Pharmacogenpmics (PG)

Author: Tilda Barliya PhD

In response to the previous post:

Paclitaxel vs Abraxane (albumin-bound paclitaxel)

http://pharmaceuticalintelligence.com/2012/11/17/paclitaxel-vs-abraxane-albumin-bound-paclitaxel/

Pharmacogenomics properties are presented, below.

Paclitaxel is a mitotic inhibitor used in cancer chemotherapy. It was discovered in a U.S. National Cancer Institute program at the Research Triangle Institute (North Carolina) in 1967 when Monroe E.Wall and Mansukh C.Wani isolated it from the bark of the Pacific yew tree, Taxus brevifolia and named it taxol. Later it was discovered that endophytic fungi in the bark synthesize paclitaxel.

Paclitaxel is currently being indicated to lung, breast and ovarian cancer as well as head and neck cancer, and advanced forms of Kaposi’s sarcoma.

The administration of paclitaxel (Taxol®) through intravenous infusions was achieved by using Cremophor® EL as a vehicle to entrap the drug in micelles and keep it in solution, which affects the disposition of paclitaxel and is responsible for the nonlinear pharmacokinetics of the drug, especially at higher dose levels. (http://www.futuremedicine.com/doi/pdf/10.2217/pgs.10.32)

Although Nonlinear pharmacokinetics (dose-dependented kinetics) may occur in all aspects of pharmacokinetics (absorption, distribution, and/or elimination), it focus on the in the metabolism or MichaelisMenten (MM) kinetics of the drug. http://archive.ajpe.org/legacy/pdfs/aj650212.pdf

Briefly, it is known that some of these adverse effects such as hypersensitivity reactions were diminished with the administration of corticosteroids and H1 and H2 antihistamine premedication, and by reducing the incidence of grade 3/4 neutropenia with the administration of granulocyte colony-stimulating factors (G-CSF) and shortening paclitaxel infusion time from 24 to 3 h. However, the neurotoxicity, which was believed to be caused by either paclitaxel or Cremophor EL, could not be controlled and became the dose-limiting toxicity of the drug. It was later on found that paclitaxel itself was responsible to the neurotoxicity effects (http://annonc.oxfordjournals.org/content/6/7/699.abstract)

Pharmacokinetics and Pharmacodynamics

The selection of pharmacokinetic (PK) parameter end points and basic model types for exposure-toxicity relationships of paclitaxel is usually based on tradition rather than physiological relevance.

pharmacokinetic (PK)-pharmacodynamic (PD) relationships for paclitaxel are still most commonly described with empirically-designed threshold models, which have little or no mechanistic basis and lack usefulness when applied to conditions (eg, schedules, vehicles, or routes of administration) different from those from which they were originally derived. (http://jco.ascopubs.org/content/21/14/2803.long). As such, the AUC of the unbound paclitaxel is highly important as a pharmacokinetic parameter to describe exposure-neutropenia relationships (the unbound ptx was not evaluated yet). (http://clincancerres.aacrjournals.org.rproxy.tau.ac.il/content/1/6/599.full.pdf+html)

The clearance of Cremophor EL in patients was found to be time-dependent, resulting in disproportional increases in systemic exposure being associated with shortening of infusion from 3 hours to 1 hour.

One study (http://clincancerres.aacrjournals.org/content/1/6/599), compare the pharmacokinetics and pharmacodynamics (PD) of paclitaxel between Phase I trials of 3- and 24-h infusions and to determine the most informative pharmacokinetic parameter to describe the PD. The study had 3 main goals

(a) to compare the PK and PD of paclitaxel between Phase I studies of 3- and 24-h infusion,
(b) to examine the relationship between PK and PD
(c) to determine the most informative pharmacokinetic parameter to describe the PD.

Note: Although this study was conducted in ~1993-1995, is has been cited extensively and paved the was to other clinical trials with similar results.

27 patients were treated in a Phase I study of paclitaxel by a 3-h infusion at one of six doses: 105, 135, 180, 210, 240, and 270 mg/m2. Pharmacokinetic data were obtained from all patients. Paclitaxel concentrations were measured in the plasma and urine using HPLC. Similar eligibility criteria were designed for the 24-hr infusion with these doses were 49.5, 75, 105, 135, and 180 mg/m2 . Plasma and urine samples for pharmacokinetic evaluation of paclitaxel were collected.

Pharmacokinetic Analysis: Pharmacokinetic parameters, Cmax, AUC, t112, and MRT were obtained by a noncompartmental moment method. Cmax was actually observed peak concentration. AUC and MRT were computed by trapezoidal integration with extrapolation to infinite time.

Pharmacodynamic Analysis: The pharmacokinetic/pharmacodynamic relationships were modeled with the sigmoid maximum effect

Results:

Pharmacokinetic analysis:

The drug plasma concentration increased throughout the 3-h infusion period and began to decrease immediately upon cessation of the infusion with t112 of 9.9-16.0 h and MRT of 6.47-10.24 h (Fig. 1). Both Cmax and AUC increased with increasing doses (r = 0.865, P <0.001 for Cmax r 0.870, P < 0.001 for AUC), although the pharmacokinetic behavior appeared to be nonlinear (Fig. 2). The mean Cmax and AUC at a dose of 270 mg/m2 were more than 3-fold greater than those at a dose of 135 mg/m2. CL and V, decreased with increasing doses (Table 1). The urinary excretion of paclitaxel over 75 h was less than 15% of the dose administered, which indicated that non-renal excretion is the primary route of drug elimination.

The urinary excretion of paclitaxel over 75 h was less than 15% of the dose administered, which indicated that non-renal excretion is the primary route of drug elimination.

Comparison of PD between 3-h and 24-h Infusion

Groups. AUC and duration of plasma concentration (h) above (7>) 0.05-0.1 LM correlated with the % D in granulocytes with p values less than 0.05. The best parameter predicting granulocytopenia was T> 0.09 pM with the minimum of the Akaike Information Criterion. In the 24-h schedule, dose, AUC, and T > 0.04-0.07 pM were demonstrated to correlate with the % D in granulocytes. The best parameter predicting granulocytopenia in the 24-h schedule was T > 0.05 p.M.

Nonhematological toxicities such as peripheral neuropathy, hypotension, and arthralgialmyalgia mainly observed in the 3-h infusion group had no relationship with Cm or AUC which are much higher in the 3-h infusion group, although peripheral neuropathy and musculoskeletal toxicity have been suggested to be associated with AUC on a 6- (12) or 24-h (29) schedule.

Pharmacogenomics:

In the past, the major adverse effects encountered with Taxol were severe hypersensitivity reactions, mainly attributed to Cremophor EL; hematologic toxicity, primarily appearing in the form of severe neutropenia; and neurotoxicity, mainly seen as cumulative sensory peripheral neuropathy. The mechanism for the neurotoxicity has been demonstrated to involve ganglioneuropathy and axonopathy caused by dysfunctional microtubules in dorsal root ganglia, axons and Schwann cells.

Variability in paclitaxel pharmacokinetics has been associated with the adverse effects of the drug. Thus, polymorphisms in genes encoding paclitaxel-metabolizing enzymes, transporters and therapeutic targets have been suggested to contribute to the interindividual variability in toxicity and response.

Further characterization of genes involved in paclitaxel elimination and drug response was performed, including the identification of their most relevant genetic variants. The organic anion transporting polypeptide (OATP) 1B3 was identified as a key protein for paclitaxel hepatic uptake and polymorphisms in the genes encoding for paclitaxel metabolizing enzymes and transporters (CYP2C8, CYP3A4) CYP3A5, P-glycoprotein and OATP1B3) (http://www.futuremedicine.com/doi/pdf/10.2217/pgs.10.32)

***It is important to note that the allele frequencies for many of these polymorphisms are subject to important ethnicity specific differences, with some alleles exclusively present in specific populations (e.g., the Caucasian CYP2C8*3).

For the CYP2C8 gene, two alleles common in Caucasians that result in amino acid changes CYP2C8*3 (R139K; K399R) and CYP2C8*4 (I264M), were described. The former has been shown to possess an altered activity, while the latter does not seem to have functional
consequences. In addition, two CYP2C8 haplotypes were recently shown to confer an increased and reduced metabolizing activity, respectively.

CYP3A5 was found to be highly polymorphic owing to CYP3A5*3, CYP3A5*6 and CYP3A5*7 , with the latter two being African-specific polymorphisms.

Pharmacogenetic studies comparing the most relevant polymorphisms in these genes and paclitaxel pharmacokinetics have rendered contradictory results, with some studies finding no associations while others reported an effect for ABCB1, CYP3A4 or CYP2C8 polymorphisms on specific pharmacokinetic parameters.

Again, with respect to paclitaxel neurotoxicity risk, some studies have rendered positive results for ABCB1 , CYP2C8 and CYP3A5 polymorphisms, while others found no significant associations.

Note: These differences might be caused by underpowered studies and by differences in the patients under study.

Changes affecting microtubule structure and/or composition have been shown to affect paclitaxel efficacy, probably by reducing drug–target affinity. Mainly, resistance to tubulin-binding agents has been associated with an overexpression of b-tubulin isotype III,
which seems to be caused by a deregulation of the microRNA family 200.

However, the clinical utility of these findings remains to be established; furthermore, the identification of biomarkers that could be used to individualize paclitaxel treatment remains a challenge.

In summary,

Pharmacokinetics: Paclitaxel seems to have a non-linear (=dose-dependent) PK parameters.
Pharmcokinetics- Pharmacodynamics: Previous clinical trials did NOT take into account the unbound concentrations of Ptx and therefore in the PK analysis, therefore newly designed clinical trials should take that into consideration. This is very important since the neurotoxicity is attributed to ptx and not its vehicle Cremophor (as shown in the PD analysis)
Difficult to compare between the 3hr and 24hr infusion schedule as most clinical trials did NOT used similar dose-regime making the comparison very hard.
Pharmacogenetics: Different polymorphisms seems to attribute to the been suggested to contribute to the interindividual variability in toxicity and response.
Prospective pharmacogenetic-guided clinical trials will be required in order to accurately establish the utility of the identified markers/strategies for patients and healthcare systems.

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Paclitaxel vs Abraxane (albumin-bound paclitaxel)

Author: Tilda Barliya PhD

Word Cloud by Daniel Menzin

Taxanes, are diterpenes produced by the plants of the genus Taxus (yews), and are widely used as chemotherapy agents. Taxane agents include paclitaxel (Taxol) and docetaxel (Taxotere). The taxane class of drugs inhibit the microtubules by stabilizing GDP-bound tubulin in the microtubule, thereby inhibiting the process of cell division. Paclitaxel (trade name Taxol) is dissolved in Cremophor EL and ethanol, as a delivery agent and much of the clinical toxicity of paclitaxel is associated with the solvent Cremophor EL in which it is dissolved.

Albumin-bound paclitaxel (trade name Abraxane, also called nab-paclitaxel) is an alternative formulation where paclitaxel is bound to albumin nano-particles (particle size of approximately 130 nanometers). nab-Paclitaxel utilises the natural properties of albumin to reversibly bind paclitaxel, transport it across the endothelial cell and concentrate it in areas of tumour. The proposed mechanism of drug delivery involves, in part, glycoprotein 60-mediated endothelial cell transcytosis of paclitaxel-bound albumin and accumulation in the area of tumor by albumin binding to SPARC (secreted protein, acidic and rich in cysteine).

When evaluating paclitaxel vs the albumin-bound paclitaxel in Pharmacokinetics (PK) clinical trials, few important questions are raised:

What is the total paclitaxel?
How much FREE paclitaxel is generated by each type of drug (Taxol vs Abraxane)?
Do they have a linear or non-linear PK curves?

Few differences between Taxol (paclitaxel) and Abraxane (albumin-bound paclitaxel) are:

Time of administration; Taxol (3hrs) and Abraxane (30min)
PK curves; Taxol (non-linear and therefore less predictable) and Abraxane (linear and therefore more predictable)
Doses; Taxol (175 mg/m2) and Abraxane (260 mg/m2)

These differences affect the analysis of the results obtained from many clinical trials conducted in multiple clinical centers and need to be taken into consideration.

In 2006: single arm phase II safety study was conducted to support the approval of adjuvant breast cancer. The FDA published the Clinical PK Comparison of Total Paclitaxel Study c008-0

Sparreboom A. et al Clin Cancer Res 2005; 11:4136-4143

Study Design:

Randomized, Phase 3, open label
Sample size: 460 patients
70 sites: Russia (77%), UK (15%), Canada and US (9%)
2 Arm: Abraxane 260 mg/m2 as a 30-minute infusion and Taxol 175 mg/m2 as a 3-hour infusion
59% second line or greater and 77% previous anthracycline exposure
Designed to show non inferiority in RR

Parameter (mean ± %CV)	Abraxane 260 mg/m2 (n=14)	Taxol 175 mg/m2 (n=12)	Abraxane/taxol Ratio	Abraxane* Dose-adjusted (n=14)	Taxol* Dose-adjusted (n=12)	Abraxane/taxol Ratio
Cmax (ng/ml)	22969	3543	6.5 x	89	20	4.4 X
AUC0-∞ (ng-hr/ml)	14789	12603	1.17 x	57	72	0.80 x
CL *(L/hrm2)**	21	15	1.43 x (43%)	21	15	1.43 x (43%)
Vz (L/m2)	664	433	1.53 x (53%)	664	433	1.53 x (53%)

FREE paclitaxel was NOT measured!!!!

Toxicity profile:

Taxol has a higher incidence of neutropenia and hypersensitivity reactions
Abraxane has a higher incidence of peripheral neuropathy, nausea, vomiting, diarrhea and asthenia

Overall Survival:

There was no difference in overall survival between the Abraxane and Taxol treatment groups. HR (Abraxane/Taxol) was 0.90, p=0.348 (log rank).
No conclusions can be drawn from a subgroup analysis when the main analysis was not statistically significant.
Multiple subgroup analyses using different criteria without p value adjustments
P-values are not interpretable

In the presentation at the American Society of Clinical Oncology (ASCO) meeting in Chicago, many eyebrows have been raised over Abraxane vs Paclitaxel study (http://www.pharmatimes.com/article/12-06 05/Eyebrows_raised_at_ASCO_over_Abraxane_vs_paclitaxel_study.aspx)

The Phase III study enrolled 799 patients with locally advanced or metastatic breast cancer who were randomised to receive one of the three therapies – paclitaxel (the standard of care), Abraxane (nanoparticle albumin bound -‘nab’ – paclitaxel) or Ixempra (ixabepilone) – on a weekly basis with each cycle consisting of three weeks of treatment followed by a one-week break. Some 98% of patients also received Roche’s Avastin (bevacizumab), which had its approval for breast cancer revoked by the US Food and Drug Administration in November 2011.

The data from the study, presented at ASCO by lead investigator Hope Rugo at the University of California, San Francisco, stated that median progression-free survival was 10.6 months for those receiving paclitaxel, 9.2 months for nab-paclitaxel, and 7.6 months for ixabepilone. Abraxane was NO better than paclitaxel ! The major surprise was over the 150mg high does chosen for the Abraxane arm, well above the 100mg for which Abraxane is approved in over 40 or so countries,

However, when searching the literature and evaluating multiple publications, Abraxane seems to be more efficacious over Taxol

Benefits of Abraxane vs. Taxol or Onxal are:
– more effective at treating tumors because a higher dosage can be delivered.
– decrease in side effects from solvent related hypersensitivity reactions.
– decreased use of medications to combat the solvent related hypersensitivity reactions.
– decreased time of administration.

In summary,

Abraxane (the albumin-bound paclitaxel) seems to have better benefits over the free paclitaxel as stated above. However, due to the differences in PK properties and lack of FREE drug measurements, more clinical studies needs to be conducted in order the understand the true values and differences between the two drug.