Tag Archives: Materials science

INTRODUCTION TO BIOMATERIALS FOR BIOMEDICAL ENGINEERS

An Introduction to Biomaterials

Buddy D. Ratner
University of Washington Engineered Biomaterials

Biomaterials are materials (synthetic and natural; solid and sometimes liquid) that are used in medical devices or in contact with biological systems. Biomaterials as a field has seen steady growth over its approximately half century of existence and uses ideas from medicine, biology, chemistry, materials science and engineering. There is also a powerful human side to biomaterials that considers ethics, law and the health care delivery system. This brief introduction overviews some key characteristics of the field of biomaterials and outlines issues and major subdivisons.

BRAIN CANCER STOPPED USING VENOM

BRAIN CANCER STOPPED BY SCORPION VENOM
Cutting the Spread of Tumors
Scientists have been looking at chlorotoxin, a peptide in scorpion venom, for the past decade as a way to target cancer cells. And the big payday has arrived. By combining nanoparticles with a scorpion venom mix already being investigated for treating brain cancer, University of Washington researchers found they could cut the spread of cancerous cells by 98 percent, compared to 45 percent for the scorpion venom alone (www.uwnews.org).
This is the first time that nanoparticles, which are ultrafine particles, have been combined with a treatment that physically stops cancer’s spread. “People talk about the treatment being more effective with nanoparticles but they don’t know how much, maybe 5 percent or 10 percent,” said Miqin Zhang, professor of materials science and engineering.  “This was quite a surprise to us.”  She is lead author of the study.
Chlorotoxin binds to a surface protein on many types of tumors, including brain cancer.  Chlorotoxin also disrupts the spread of tumors.
The Whole is Greater than the Parts
The researchers investigated chlorotoxin when it is attached to nanoparticles and found that the treatment’s effect doubles compared to chlorotoxin alone.  Adding nanoparticles often improves a therapy, partly because the combination lasts longer in the body and so has a better chance of reaching the tumor.  Combining also boosts the effect because therapeutic molecules clump around each nanoparticle.
Slowing the spread of cancer would be especially useful for treating highly invasive tumors, such as brain cancer.  The technique could hypothetically also slow the spread of other tumors with the same kind of activity, such as breast, colon, skin, lung, prostate, and ovarian cancers.