Islamabad,
Jan 31 : Bioengineers at Tufts University School of Engineering have
developed a new silk-based microneedle system able to deliver precise amounts of
drugs over time and without need for refrigeration.
The tiny needles can
be fabricated under normal temperature and pressure and from water, so they can
be loaded with sensitive biochemical compounds and maintain their activity prior
to use. They are also biodegradable and biocompatible.
The Tufts
researchers successfully demonstrated the ability of the silk microneedles to
deliver a large-molecule, enzymatic model drug, horseradish peroxidase (HRP), at
controlled rates while maintaining bioactivity. In addition, silk microneedles
loaded with tetracycline were found to inhibit the growth of Staphylococcus
aureus, demonstrating the potential of the microneedles to prevent local
infections while also delivering therapeutics.
"By adjusting the
post-processing conditions of the silk protein and varying the drying time of
the silk protein, we were able to precisely control the drug release rates in
laboratory experiments," said Fiorenzo Omenetto, Ph.D., senior author on the
paper. "The new system addresses long-standing drug delivery challenges, and we
believe that the technology could also be applied to other biological storage
applications."
While some drugs can be swallowed, others can't survive
the gastrointestinal tract. Hypodermic injections can be painful and don't allow
a slow release of medication. Only a limited number of small-molecule drugs can
be transmitted through transdermal patches. Microneedles -- no more than a
micron in size and able to penetrate the upper layer of the skin without
reaching nerves -- are emerging as a painless new drug delivery mechanism. But
their development has been limited by constraints ranging from harsh
manufacturing requirements that destroy sensitive biochemicals, to the inability
to precisely control drug release or deliver sufficient drug volume, to problems
with infections due to the small skin punctures.
The process developed by
the Tufts bioengineers addresses all of these limitations. The process involves
ambient pressure and temperature and aqueous processing. Aluminum microneedle
molding masters were fabricated into needle arrays of about 500 µm needle height
and tip radii of less than 10 µm. The elastomer polydimethylsiloxane (PDMS) was
cast over the master to create a negative mold; a drug-loaded silk protein
solution was then cast over the mold. When the silk was dry, the
drug-impregnated silk microneedles were removed. Further processing through
water vapor annealing and various temperature, mechanical and electronic
exposures provided control over the diffusity of the silk microneedles and drug
release kinetics.
"Changing the structure of the secondary silk protein
enables us to 'pre-program' the properties of the microneedles with great
precision," said David L. Kaplan, Ph.D., coauthor of the study, chair of
biomedical engineering at Tufts and a leading researcher on silk and other novel
biomaterials. "This is a very flexible technology that can be scaled up or down,
shipped and stored without refrigeration and administered as easily as a patch
or bandage. We believe the potential is enormous."
Other co-authors on
the paper, all associated with the Department of Biomedical Engineering, are
Konstantinos Tsioris, doctoral student; Waseem Raja, post-doctoral associate;
Eleanor Pritchard, post-doctoral associate; and Bruce Panilaitis, research
assistant professor.
Ends
SA/EN
Home »
» Silk microneedles deliver controlled-release drugs painlessly
Silk microneedles deliver controlled-release drugs painlessly
Subscribe to:
Post Comments (Atom)
0 comments:
Post a Comment