The shear-activated
nanotherapeutic breaks apart and releases its drug when it encounters regions
of vascular narrowing. Credit: Wyss Institute
Researchers at the
Wyss Institute for Biologically Inspired Engineering at Harvard University have
developed a novel biomimetic strategy that delivers life-saving
nanotherapeutics directly to obstructed blood vessels, dissolving blood clots
before they cause serious damage or even death. This new approach enables
thrombus dissolution while using only a fraction of the drug dose normally
required, thereby minimizing bleeding side effects that currently limit
widespread use of clot-busting drugs.
The research findings, which were published online today
in the journalScience, have significant implications for treating major
causes of death, such as heart attack, stroke, and pulmonary embolism, that are
caused by acute vascular blockage by blood thrombi.
The inspiration for the targeted vascular nanotherapeutic
approach came from the way in which normal blood platelets rapidly adhere to
the lining of narrowed vessels, contributing to the development of atherosclerotic
plaques. When vessels narrow, high shear stresses provide a physical cue
for circulating platelets to stick to the vessel wall selectively
in these regions. The vascular nanotherapeutic is similarly about the size of a
platelet, but it is an aggregate of biodegradable nanoparticles that
have been coated with the clot-busting drug, tissue
plasminogen activator (tPA).
Much like when a wet ball of sand breaks up into
individual grains when it is sheared between two hands, the aggregates
selectively dissociate and release tPA-coated nanoparticles that bind to clots
and degrade them when they sense high shear stress in regions of vascular
narrowing, such as caused by blood clot formation.
Disruption of normal blood flow to the heart, lung, and
brain due to thrombosis is one of the leading causes of death and long-term
adult disability in the developing world. Today, patients with pulmonary embolism,
strokes, heart attacks, and other types of acute thrombosis leading to
near-complete vascular occlusion, are most frequently treated in an acute care
hospital setting using systemic dosages of powerful clot-dissolving drugs.
Because these drugs can cause severe and often fatal bleeding as they circulate
freely throughout the body, the size of the dosage given to any patient is
limited because efficacy must be balanced against risk.
The new shear-activated nanotherapeutic has the potential
to overcome these efficacy limitations. By targeting and concentrating drug at
the precise site of the blood vessel obstruction, the Wyss team has been able
to achieve improved survival in mice with occluded lung vessels with less than
1/50th of the normal therapeutic dose, which should translate into fewer side
effects and greater safety. This raises the possibility that, in the future, an
emergency technician might be able immediately administer this nanotherapeutic
to anyone suspected of having a life-threatening blood clot in a vital organ
before the patient even reached the hospital.
The inter-disciplinary and inter-institutional
collaborative research team, which was led by Wyss Founding Director Donald
Ingber M.D., Ph.D., and Wyss Technology Development Fellow Netanel Korin,
Ph.D., also included Wyss postdoctoral Fellow Mathumai Kanapathipillai, Ph.D.,
as well as Benjamin D. Matthews, Marilena Crescente, Alexander Brill, Tadanori
Mammoto, Kaustabh Ghosh, Samuel Jurek, Sidi A. Bencherif, Deen Bhatta, Ahmet U.
Coskun, Charles L. Feldman, and Denisa D. Wagner from Brigham and Women's
Hospital, Children's Hospital Boston, Harvard Medical School, the Harvard
School of Engineering and Applied Sciences, and Northeastern University. Ingber
is also the Judah Folkman Professor of Vascular Biology at Harvard Medical
School and Children's Hospital Boston, and Professor of Bioengineering at
Harvard's School of Engineering and Applied Sciences.
Commenting on the work, Ingber noted that "the
vascular nanotherapeutic we developed that selectively becomes activated in
regions of high shear stress, much like living platelets do, is a wonderful
example of how we at the Wyss Institute take inspiration from biology, and how
biomimetic strategies can lead to new and unexpected solutions to age-old
problems that existing technologies can't address."
More information: "Shear-Activated
Nanotherapeutics for Drug Targeting to Obstructed Blood Vessels," by N.
Korin et al., Science, 2012.
Provided by Harvard University
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