The present investigation reports polymer topology design principle for programming the enzymatic biodegradation and delivery of anticancer drugs at the intracellular compartments of breast and cervical cancers. To accomplish this goal, new classes of biodegradable amphiphilic block and random copolymers based on hydrophilic carboxylic-functionalized polycaprolactone (CPCL) and hydrophobic polycaprolactone (PCL) units were designed via ring-opening polymerization methodology. The interchain interactions and their packing were directly controlled by the topology of the polymers, and the block copolymers were found to be as semicrystalline materials. These amphiphilic block and random polymers were readily dispersible in water, and they self-assembled into <200 nm nanoparticles. These nanoparticles exhibited excellent capability for loading anticancer drug doxorubicin (DOX) in the hydrophobic pocket. In vitro drug release kinetics revealed that the polymer nanoscaffolds were stable under physiological conditions, and they exclusively ruptured in the presence of lysosomal esterase enzyme at the intracellular compartments to deliver DOX. The “burst” and “controlled” release of drugs from the polymer nanocarriers was directly controlled by length and chemical composition of block and random copolymers. In vitro cytotoxicity studies in breast cancer (MCF 7) and cervical cancer (HeLa) cells revealed that the nascent polymer nanoparticle was highly biocompatible and nontoxic to cells whereas their DOX-loaded nanoparticles accomplished >95% cell killing. Confocal microscopy reinstated the cellular uptake of the DOX-loaded polymer scaffold wherein the nanoparticle was highly concentrated at the nucleus and revealed that the drugs were predominantly delivered at the nucleus of the cells for apoptosis. Flow cytometry investigation confirmed the enhanced DOX delivering capability of block and random copolymer nanoparticles compared to free DOX. The newly designed fully biodegradable PCL-based block and random nanocarriers are excellent scaffolds for enzyme-mediated intracellular delivery of DOX, and the proof of concept was established in breast and cervical cancers.
We report a biodegradable fluorescent theranostic nanoprobe design strategy for simultaneous visualization and quantitative determination of antibacterial activity for the treatment of bacterial infections. Cationic-charged polycaprolactone (PCL) was tailor-made through ring-opening polymerization methodology, and it was self-assembled into well-defined tiny 5.0 ± 0.1 nm aqueous nanoparticles (NPs) having a zeta potential of +45 mV. Excellent bactericidal activity at 10.0 ng/mL concentration was accomplished in Gram-negative bacterium Escherichia coli (E. coli) while maintaining their nonhemolytic nature in mice red blood cells (RBC) and their nontoxic trend in wild-type mouse embryonic fibroblast cells with a selectivity index of >10 4 . Electron microscopic studies are evident of the E. coli membrane disruption mechanism by the cationic NP with respect to their high selectivity for antibacterial activity. Anionic biomarker 8-hydroxy-pyrene-1,3,6-trisulfonic acid (HPTS) was loaded in the cationic PCL NP via electrostatic interaction to yield a new fluorescent theranostic nanoprobe to accomplish both therapeutics and diagnostics together in a single nanosystem. The theranostic NP was readily degradable by a bacteria-secreted lipase enzyme as well as by lysosomal esterase enzymes at the intracellular compartments in <12 h and support their suitability for biomedical application. In the absence of bactericidal activity, the theranostic nanoprobe functions exclusively as a biomarker to exhibit strong greenfluorescent signals in live E. coli. Once it became active, the theranostic probe induces membrane disruption on E. coli, which enabled the costaining of nuclei by red fluorescent propidium iodide. As a result, live and dead bacteria could be visualized via green and orange signals (merging of red+green), respectively, during the course of the antibacterial activity by the theranostic probe. This has enabled the development of a new image-based fluorescence assay to directly visualize and quantitatively estimate the real-time antibacterial activity. Time-dependent bactericidal activity was coupled with selective photoexcitation in a confocal microscope to demonstrate the proof-of-concept of the working principle of a theranostic probe in E. coli. This new theranostic nanoprobe creates a new platform for the simultaneous probing and treating of bacterial infections in a single nanodesign, which is very useful for a longterm impact in healthcare applications.
The present investigation reports enzyme-biodegradable perylenebisimide (PBI)-tagged polycaprolactone (PCL) block copolymers, and their aqueous nanoassemblies were employed as probes for intracellular bio-imaging in cancer cells. Bishydroxyl functionalized PBI initiator was tailor-made, and it was employed as initiator for the ring opening polymerization (ROP) methodology to make PBI-tagged tert-butyl ester-substituted polycaprolactone (PBI-BPCL x ) block copolymers. The deprotection of these copolymers yielded carboxylic acid-substituted PBI-CPCL x amphiphilic block copolymers. The carboxylic blocks were self-assembled to produce stable red-fluorescent nanoparticles of <150 nm in size in aqueous medium with fluorescent quantum yield of ϕ = 0.25–0.30 suitable for bio-imaging application. In vitro studies confirmed that the aliphatic polyester backbone in the PBI-CPCL x polymer nanoparticles was readily biodegradable by lysosomal enzymes under physiological conditions. Dynamic light scattering, gel permeation chromatography, photophysical studies, and MALDI-TOF-MS analysis provided evidence of the enzymatic biodegradation. Cytotoxicity studies revealed that the PBI-CPCL x nanoparticles were highly biocompatible toward both cervical cancer and breast cancer cell lines up to a concentration of 100 μg/mL. Confocal microscopy analysis confirmed the uptake and accumulation of red-fluorescent PBI-CPCL x polymer nanoparticles in the perinuclear environment of the cells. The present approach puts forward a PBI-PCL block copolymer design as enzyme-responsive red-fluorescent nanoprobes for bio-imaging in cancer and normal cells.
The present investigation reports the structural engineering of biodegradable star block polycaprolactone (PCL) to tailor-make aggregated micelles and unimolecular micelles to study their effect on drug delivery aspects in cancer cell lines. Fully PCL-based star block copolymers were designed by varying the arm numbers from two to eight while keeping the arm length constant throughout. Multifunctional initiators were exploited for stepwise solvent-free melt ring-opening polymerization of ε-caprolactone and γ-substituted caprolactone to construct star block copolymers having a PCL hydrophobic core and a carboxylic PCL hydrophilic shell, respectively. A higher arm number and a higher degree of branching in star polymers facilitated the formation of unimolecular micelles as opposed to the formation of conventional multimicellar aggregates in lower arm analogues. The dense core of the unimolecular micelles enabled them to load high amounts of the anticancer drug doxorubicin (DOX, ∼12–15%) compared to the aggregated micelles (∼3–4%). The star unimolecular micelle completely degraded leading to 90% release of the loaded drug upon treatment with the lysosomal esterase enzyme in vitro. The anticancer efficacies of these DOX-loaded unimolecular micelles were tested in a breast cancer cell line (MCF-7), and their IC50 values were found to be much lower compared to those of aggregated micelles. Time-dependent cellular uptake studies by confocal microscopy revealed that unimolecular micelles were readily taken up by the cells, and enhancement of the drug concentration was observed at the intracellular level up to 36 h. The present work opens new synthetic strategies for building a next-generation biodegradable unimolecular micellar nanoplatform for drug delivery in cancer research.
Monitoring intracellular administration of nonluminescent anticancer drugs like cisplatin is a very challenging task in cancer research. Perylenebisimide (PBI) chromophore tagged fluorescent ABC-triblock polycaprolactone (PCL) nanoscaffold was engineered having carboxylic acid blocks for the chemical conjugation of cisplatin at the core and hydrophilic PEG blocks at the periphery. The amphiphilic ABC triblock Pt-prodrug was self-assembled into < 200 nm nanoparticles and exhibited excellent shielding against drug detoxification by the glutathione (GSH) species in the cytosol.In vitro drug release studies confirmed that the Pt-prodrug was stable at extracellular conditions and the PCL block exclusively underwent lysosomal-enzymatic biodegradation at the intracellular level to release the cisplatin drug in the active-form for accomplishing more than 90% cell growth inhibition. Confocal microscopic imaging of the redfluorescence signals from the perylene chromophores established the simultaneous monitoring and delivery aspects of the Pt-prodrug, and the proof-of-concept was successfully demonstrated in breast and cervical cancer cell lines.
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