2016
DOI: 10.1002/pola.28216
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Enzyme and pH dual responsive l -amino acid based biodegradable polymer nanocarrier for multidrug delivery to cancer cells

Abstract: We report a new pH and enzyme dual responsive biodegradable polymer nanocarrier to deliver multiple anticancer drugs at the intracellular compartment in cancer cells. Natural L-aspartic acid was converted into multifunctional monomer and polymerized to yield new classes of biodegradable aliphatic polyester in-build with pH responsiveness. The transformation of side chain BOC urethanes into cationic NH 1 3 in the acidic endosomal environment disassembled the polymers nanoparticles (pH trigger-1). The biodegrada… Show more

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Cited by 32 publications
(49 citation statements)
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“…Saxena and Jayakannan reported a new pH‐responsive and enzyme‐degradable amphiphilic aliphatic polyester, which was synthesized from natural l ‐amino acid resources and could self‐assemble into NPs . In cancer cells, the acidic endosomal environment caused the disassembly of NPs due to the transformation of side‐chain of tert ‐butyl decarbonate‐protected urethanes into cationic NH 3 + , and the lysosomal esterase enzyme induced the cleavage of ester bonds in polymer backbones (Figure A).…”
Section: Stimuli‐responsive Drug‐release Nanosystemsmentioning
confidence: 99%
“…Saxena and Jayakannan reported a new pH‐responsive and enzyme‐degradable amphiphilic aliphatic polyester, which was synthesized from natural l ‐amino acid resources and could self‐assemble into NPs . In cancer cells, the acidic endosomal environment caused the disassembly of NPs due to the transformation of side‐chain of tert ‐butyl decarbonate‐protected urethanes into cationic NH 3 + , and the lysosomal esterase enzyme induced the cleavage of ester bonds in polymer backbones (Figure A).…”
Section: Stimuli‐responsive Drug‐release Nanosystemsmentioning
confidence: 99%
“…Another disadvantage is that esterase activity in tumor cells is different from person to person (Niu et al., 2012). In that case, some nanoparticles can respond to multi-stimuli simultaneously, such as GSH/esterase (Lv et al., 2015), pH/esterase (Fernando et al., 2015; Saxena & Jayakannan, 2016), heat/esterase (Kashyap et al., 2016; Aluri et al., 2018), etc. A multi-stimulus responsive drug carrier can simultaneously respond to different stimulating factors in tumor tissues and cells, not only can promote the uptake of drug conjugates by cells, but also promote the releasing of drugs in tumors, allowing the drug to function better in target cells.…”
Section: Perspectivesmentioning
confidence: 99%
“…Degradation of polymeric structure can be achieved by breaking down the enzyme-responsive groups in the polymer chain (Figure 10a). These enzymeresponsive groups can be located in the end group of the polymer chain, along the main chain, and at the junction of two different blocks of block copolymers [376,[380][381][382]. In Figure 10b, changes occur in the hydrophilicity of the polymer chain by enzyme-responsive group separation or addition of the side groups in the polymer chain [383,384].…”
Section: Biochemical Stimuli-responsive Polymersmentioning
confidence: 99%