Poly(lactide-co-glycolide)-FPR648

Biomedical polymeric materials are a type of polymeric materials used in areas such as artificial organs, tissue engineering and regenerative medicine, in vivo and in vitro diagnostics, pharmaceutical preparations and medical devices. Among them, degradable medical polymer materials can be gradually degraded by specific or non-specific cleavage of molecular chains in the internal environment, and the degradation products can be absorbed by the body or excreted through metabolic processes. Therefore, this type of material can be automatically eliminated after fulfilling its internal mission and does not cause any secondary damage to human health. In recent years, it has become a type of biomedical material that has attracted much attention. Aliphatic polyester is a typical type of biodegradable polymer material. Among them, polylactic acid (PLA) is currently one of the most mature industrialised materials with the largest output and the most widely used materials. It has good biocompatibility and biodegradability properties. Degradability etc. However, under homogeneous conditions, PLA has weak nucleation ability and low crystallization rate. Conventional processing methods can only produce products with low crystallinity or even amorphous state, resulting in greatly reduced mechanical properties and heat resistance. At the same time, PLA has poor hydrophilicity and degradation. The cycle is long, and these limitations have restricted the application of PLA to a certain extent. Polyglycolic acid (PGA) is one of the fastest degrading aliphatic polyester materials at present, and the degradation conditions are mild. It can be degraded into carbon dioxide and water in the natural environment. At the same time, due to its regular structure, its crystallization properties are better than PLA, and it has It has good mechanical properties and gas barrier properties, but it also has disadvantages such as difficult processing and insufficient toughness. By copolymerising lactic acid (LA) and glycolic acid (GA), the advantages of PLA and PGA can be fully exploited and their respective shortcomings compensated for. The resulting PLGA has good degradability, biocompatibility, excellent mechanical properties and heat resistance. Its properties and controlled degradation make it one of the first batches of degradable medical polymer materials to be certified by the US Food and Drug Administration (FDA). It is widely used in areas such as controlled drug release, medical fibre materials and bone tissue engineering scaffolds. PLGA is generally a white solid with a glass transition temperature of 40-60°C. PLGA is in a glassy state at room temperature and its molecular chain exhibits strong rigidity. It is generally an amorphous or semicrystalline polymer. Studies have shown that different polymerisation methods, different comonomer ratios and relative molecular weights give PLGA different aggregation structures, which affect its hydrophilicity, mechanical strength and biodegradation rate.

Figure 1. Schematic representation of chemical structure for PLGA and its monomers. (Alsaab HO, et al.; 2022)

Due to the good performance and biocompatibility of PLGA, its main application is in the medical field, where it is used as a sustained-release drug carrier, absorbable surgical sutures, tissue engineering and other medical materials. PLGA has the characteristics of controlled biodegradation and can also be used as a packaging material. The degradation products of PLGA are L-LA and GA, both of which can be naturally degraded in the body, so they have good biocompatibility and low toxicity. PLGA has been widely studied and applied in drug delivery systems and has been reported in drug delivery systems such as nanoparticles, microspheres, implants and nanofibres. PLGA can carry a wide range of drugs, from small molecule drugs to protein drugs, from hydrophilic drugs to lipophilic drugs, and from single-component drugs to multi-component drugs. From research and clinical experience, PLGA is one of the most widely used polymers in nanomedicine drug delivery systems. PLGA is also used for vaccines. Antigens can be formulated into PLGA nanoparticles and the prolonged release of antigens can provide more effective immune protection. PLGA can also be used in cancer immunotherapy. Compared to traditional sutures, which must be removed, PLGA surgical sutures are degradable and absorbable, and their strength meets suture requirements. PLGA is suitable for bone tissue materials due to its good biodegradability and compatibility, good mechanical properties, low toxicity, etc. However, it must be combined with other materials to improve the poor conductivity of PLGA. PLGA is also popular in regenerative medicine.

Alternate Names:
PLGA-FPR648
Poly(lactic-co-glycolic acid)-FPR648
Poly(lactide-co-glycolide)-FPR648
Poly(lactic acid-co-glycolic acid)-FPR648
PLGA-Dye FPR648
Poly(lactide-co-glycolide) conjugated with FPR648

References:
1. Alsaab HO, et al.; PLGA-Based Nanomedicine: History of Advancement and Development in Clinical Applications of Multiple Diseases. Pharmaceutics. 2022, 14(12):2728.
2. Su Y, et al.; PLGA-based biodegradable microspheres in drug delivery: recent advances in research and application. Drug Deliv. 2021, 28(1):1397-1418.

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