drugs, antimicrobials, proteins delivery, and tissue repair. PBAEs are synthesized via a one-pot Michael addition of amines to acrylates (Scheme 1) without the production of any byproducts. The hydrolytically degradable ester bonds provide PBAEs with excellent biodegradability, thus reducing the cytotoxicity caused by necrosis and apoptosis. [5] The tertiary amine groups can electrostatically interact with negatively charged gene [6] or therapeutics [7] to form nanocomposites. Besides, the amino groups undergo phase transition upon the charge of surrounding pH, possessing pH-responsive and charge reversible properties, [8,9] and those properties make the PBAEs promising candidates for controlled and programmable release. [10] The key factor of PBAEs is their potential for structural diversity due to the combination of different monomers. [4] In addition, PBAEs are compatible with a wide range of polymers, for instance, poly(ethylene glycol) (PEG), [11] poly (lactic acid) (PLA), [12] and poly(ε-caprolactone) (PCL) [13] to form block copolymers. Taken together, these cases demonstrated the versatility of the PBAEs in the modification of their physical, chemical, and mechanical properties. In this review, we emphasize all types of PBAE-based formulations, namely, nanocomposites, micelles, hydrogels, and films for therapeutics delivery and tissue repair applications.
MonomersDiverse acrylates (A) were employed in PBAE synthesis, as shown and classified in Figure 1. The functional groups like alkyl, aryl, and ester groups (A1-A14) are hydrophobic, which Poly(β-amino ester) (abbreviated as PBAE or PAE) refers to a polymer synthesized from an acrylate and an amine by Michael addition and has properties inherent to tertiary amines and esters, such as pH responsiveness and biodegradability. The versatility of building blocks provides a library of polymers with miscellaneous physicochemical and mechanical properties. When used alone or together with other materials, PBAEs can be fabricated into different formulations in order to fulfill various requirements in drug delivery (for instance, gene, anticancer drugs, and antimicrobials delivery) and natural complex mimicry (nanochaperones). This progress report discusses the recent developments in design, synthesis, formulations, and applications of PBAEs in biomedical fields and provides a perspective view for the future of the PBAEs.
