TEPHA INC. : TECHNOLOGY
OVERVIEW
Tepha’s proprietary technology utilizes genetic
engineering to produce designer biomaterials that can be
converted into a wide range of products that restore,
repair, or improve tissue function. Potential products
that can be constructed from these materials range from
relatively simple medical devices, such as surgical patches
and meshes, to more complex products like orthopedic repair
devices, cardiovascular stents, and tissue engineered heart
valves.
The fundamental aspects of this technology is based upon new
methods for producing a class of natural materials, called
polyhydroxyalkanoates- or PHA polymers. These polymers
are synthesized in nature by numerous microorganisms, and
they have been recently recognized as the fifth class of
naturally occurring biopolymers (along with the polyamino
acids, polynucleic acids, polysaccharides, and
polyisoprenoids). Unlike the other naturally occurring
biological polymers, however, the PHA polymers are
thermoplastic, i.e. they can be repeatedly softened with
heat and hardened with cooling. As such, these polymers can
be processed much like the plastics we use today.
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Tepha’s biomaterials are produced by proprietary
transgenic fermentation processes, similar in some respects
to those used to produce biopharmaceuticals, but with
substantially higher yields of product – often reaching 50
grams or more of biomaterial per liter. The company is
able to control the composition of the biomaterial through
the appropriate selection of genes, production vehicles,
feedstocks, and pathway engineering methods.
Use of Tepha's PHA polymers presents significant advantages
in medical applications. Studies have shown that
inside the body, the company's biomaterials are
biocompatible and non-inflammatory. They degrade by
cell friendly processes into metabolites that already exist
in humans (while some of the competing biomaterials, in
contrast, release highly inflammatory acids that impair this
process). The degradation process is particularly
important for tissue engineering, where cells need an
optimal environment for tissue regeneration. Typically,
degradation rates of Tepha’s PHA biomaterials can range
from about six weeks to over a year, allowing the Company to
develop its biomaterials for products requiring prolonged
strength retention, such as sutures for use in orthopedic
procedures or materials for ligament repair.
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Until
recently, the widespread use of such biomaterials
had been limited by the available production
technology. However, in the 1980's researchers
at the Massachusetts Institute of Technology made a
major breakthrough in the development of new
biological production systems, when they
successfully isolated the genes responsible for
making these polymers in microorganisms. Our
sister company, Metabolix, Inc. (Cambridge, MA)
first took up the challenge for using this discovery
to develop transgenic systems for the commercial
production of such polymers, and the firm
successfully developed several transgenic
fermentation methods for producing different
polymers. |
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Today, these biomaterials are being produced for medical
applications by Tepha's proprietary transgenic fermentation
processes, similar in some respects to those used to produce
biopharmaceuticals, but with substantially higher yields of
product. It is anticipated that the cost of producing
the PHA biomaterials at scale and according to Good
Manufacturing Practices (GMP) will be comparable to that for
most currently available synthetic absorbable biomaterials.
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