https://www.dolcera.com/wiki/index.php?action=history&feed=atom&title=Bioabsorable_material 2026-04-13T11:29:28Z Revision history for this page on the wiki MediaWiki 1.24wmf12 https://www.dolcera.com/wiki/index.php?title=Bioabsorable_material&diff=7038&oldid=prev 2009-10-08T20:30:48Z

<p></p> <p><b>New page</b></p><div>The use of bioabsorbable polymers in the manufacture of implants for soft tissue fixation has been clinically accepted for many years.<br /> <br /> Bioabsorbable versus Metal<br /> <br /> Bioabsorbable implants have many advantages over metal implants, including:<br /> # Load sharing versus stress shielding<br /> # Reduced risk of articular damage<br /> # MRI compatible for Post-Op diagnosis<br /> # Minimised risk of obstruction during revision surgery if required<br /> # Minimised risk of stress risers normally associated with implant removal.<br /> <br /> Bioabsorbable polymers are a special class of plastic materials that allow the material to serve a function, and then gradually break down, metabolise and be eliminated from the body.<br /> <br /> It is imperative to match the degradation time with the initial period during which the material must function.<br /> <br /> The ideal bioabsorbable material will provide appropriate strength while degrading in a predictable fashion without adverse reactions occurring in the body throughout the healing process.<br /> Specific Bioabsorbable Polymers<br /> <br /> There are three main types of bioabsorbable polymers used in orthopedics:<br /> # PGA: although highly crystalline, PGA absorbs very quickly into the body, losing virtually all strength within 1 month and all mass within about 6 to 12 months. During this phase of rapid absorption, large quantities of a glycolic acid monomer are released, potentially causing clinical complications within a few months following implantation.<br /> # PLLA: Poly (L) Lactic Acid has a much slower rate of absorption than PGA. The L (Levo) version of this polymer is highly crystalline due to the ordered pattern of the monomers, (i.e. L-L-L-L-L- L-L) and has been documented to take as much as 5-7 years to absorb.<br /> # PDLA: the D (Dexo) Isomeric form of PLA, has a much faster absorption rate.<br /> # PDLA: is a racemic mix (equal amounts of left and right - handed isomers) of Poly-Levo-Lactic Acid and Poly-Dexo-Lactic Acid. This polymer is sometimes called 50:50 PDLA in the field.<br /> <br /> Copolymers<br /> <br /> Bioabsorbable polymers are often blended into a copolymer to maximise initial strength and increase the rate of absorption.<br /> Typical blends are:<br /> <br /> * LLA/PGA: normally 80/20, this copolymer holds its mechanical strength for 6-8 weeks and is fully resorbed in approximately one year. This material is predominantly used in paediatrics. Because of the need for rapid resorption during a child's development.<br /> * L/D PLA: 9H/4D and other blends, such as 80:20 or 70:30, are available depending on the clinical requirements for initial strength versus rate of resorption. 96 U4D copolymer combines the initial strength of PLLA with a foster resorption time compared to 100% PLLA.<br /> <br /> Self-Reinforced PLA<br /> <br /> There are many ways of manufacturing bioabsorbable polymers, including compression moulding, casting, injection moulding and extrusion.<br /> <br /> An extruded bar is heated until soft and pulled through a dye in a controlled manner. This aligns the polymer chains in the direction of pulling and also entangles them to form the Self-Reinforced polymer.<br /> <br /> This Self-Reinforced polymer has high initial strength that reduces premature fracture during implant insertion. It also allows the implant to maintain holding power throughout the healing process.<br /> <br /> As with all bioabsorbable implants, they biologically resorb over time, allowing the load to transfer to the bone after primary bone healing and eventually completely disappear through safe biological resorption<br /> <br /> [http://www.shoulderdoc.co.uk/education/article.asp?article=343 source]</div>

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