Biopolymers for Biomedical and Biotechnological Applications. Группа авторов

Biopolymers for Biomedical and Biotechnological Applications - Группа авторов


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material information, existing endpoint‐specific data, or a written rationale why testing or further data is not needed to address a particular risk. In any case, the biocompatibility of a device or material must be spelled out, addressing directly each of the specific risk identified, mitigating concern through testing results or written evaluation in a biological risk assessment.

      The shift from check‐listing tests to a risk‐based approach has been motivated by several factors:

       Consideration of animal welfare, with a charge to reduce animal testing as much as possible

       A broader and better consolidated body of data on materials and toxicology

       Better analytical chemistry tools to evaluate manufacturing residuals, material leachables, and degradation products

      Knowing that the key is to protect patient safety by proving biocompatibility of a device to the skeptical reviewer while at the same time avoiding as much unnecessary testing as possible is the heart of evaluating biocompatibility using a risk‐based approach. There is an art to a biocompatibility evaluation, balancing commonsense measures to ensure safety with currently available data on one hand and the expectations of regulatory bodies across the spectrum on the other. Understanding the role the material information has and how this broadly impacts the testing strategy (along with the cost and time burden of testing) is central to the strategy.

      In the best case, material information and written assessment alone can be sufficient to mitigate and address all of the biological risks associated with a device. To be convincing, however, a great deal of detail is needed. Often, the question of biocompatibility is not about the bulk material itself at all, but rather about the processing of that material that takes place both upstream and downstream. Consider a polycaprolactone (PCL) implant, manufactured using 3D printing from a powder starting material. To the manufacturer, the name PCL along with its assigned chemical abstracts service (CAS) number defines the material. But there are many ways to synthesize PCL [4] that may influence its safety profile in terms of impurities that (while not obvious from bulk properties) will affect toxicology. Consider the PCL pipeline upstream from the device manufacturer:

      1 Preparation of the monomer (either ε‐caprolactone or 6‐hydroxycaproic acid) at raw chemical supplier:ε‐Caprolactone and 6‐hydroxycaproic acid may be produced naturally by oxidation of cyclohexanol by microorganisms and then harvested and purified (all steps removing or introducing impurities to varying degrees).ε‐Caprolactone can also be produced industrially through a reaction of cyclohexanone with peracetic acid.

      2 The monomer is purified, packaged, sold, and shipped to the maker of the polymer without knowledge that the monomer will end up in a medical device:Purity and performance metrics are based on bulk properties (not toxicological endpoints).

      3 The monomer is polymerized by another manufacturer:Polymerization occurs using a variety of different possible techniques, using different activators and/or catalysts, several of which are complex organometallic complexes of questionable safety (see, for example, those contained in Ref. [4]).

      4 The polymer is powdered and purified by the manufacturer using a proprietary cryogenic process.

      Most (or all) of the details of the upstream process are unknown to the medical device manufacturer, yet they can impact device safety. It could matter, from a toxicological perspective, if the PCL in a device is manufactured using lithium diisopropylamide or tert‐butoxy potassium as a catalyst. If the device manufacturer were to ask their polymer supplier what catalyst or what monomer is used and the method of manufacture, the information is likely considered intellectual property, and medical device manufacturers are typically not big enough customers of polymer manufacturers to be able to make demands. Therefore, in these cases, it is up to the device manufacturer to prove the biocompatibility of their materials acknowledging that very little is known about the impurity profile of their device.

      1.3.1 Chemistry of Biopolymers and Risk

Classification Example biopolymer Notes on production Risks
Polysaccharides Hyaluronic acid, HA (polymer of D‐glucuronic acid and N‐acetylglucosamine) Primarily produced using bacteria including Streptococcus Production by pathogenic bacteria coproduces myriad other potentially toxic biological products that must be removed during subsequent purification steps
Cellulose (polymer of D‐glucose) From plant products, cellulose is dissolved from other plant materials in an alkali process, followed by purification. Produced bacterially using Acetobacter xylinum [8, 9] Industrial purification steps can introduce impurities. Bacterial production coproduces myriad other potentially toxic biological products that must be removed during subsequent purification steps
Proteins Primarily from the mulberry silkworm Bombyx mori [10] Industrial post‐processing and purification steps can introduce impurities
Polyesters Polylactic acid Primarily ring‐opening polymerization of lactide (cyclic
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