Jun Akimoto

Temperature-Induced Intracellular Uptake of Thermoresponsive Polymeric Micelles

Well-defined diblock copolymers comprising thermoresponsive segments of poly(N-isopropylacrylamide-co-N,N-dimethylacrylamide) (P(IPAAm-co-DMAAm)) and hydrophobic segments of poly(d,l-lactide) were synthesized by combination of RAFT and ring-opening polymerization methods. Terminal conversion of thermoresponsive segments was achieved through reactions of maleimide or its Oregon Green 488 (OG) derivative with thiol groups exposed by cleavage of polymer terminal dithiobenzoate groups. Thermoresponsive micelles obtained from these polymers were approximately 25 nm when below the lower critical solution temperature (LCST) of 40 degrees C, and their sizes increased to an average of approximately 600 nm above the LCST due to aggregation of the micelles. Interestingly, the OG-labeled thermoresponsive micelles showed thermally regulated internalization to cultured endothelial cells, unlike linear thermoresponsive P(IPAAm-co-DMAAm) chains. While intracellular uptake of P(IPAAm-co-DMAAm) was extremely low at temperatures both below and above the micellar LCST, the thermoresponsive micelles showed time-dependent intracellular uptake above the LCST without exhibiting cytotoxicity. These results indicate that the new thermoresponsive micelle system may be a greatly promising intracellular drug delivery tool.

Temperature-responsive polymeric micelles for optimizing drug targeting to solid tumors

Targeting to solid tumors is the most challenging issue in the drug delivery field. To obtain the ideal pharmacodynamics of administrated drugs, drug carriers must suppress drug release and interactions with non-target tissues while circulating in the bloodstream, yet actively release the incorporated drug and interact with target cells after delivery to the tumor tissue. To handle this situation, stimuli-responsive drug carriers are extremely useful, because carriers change their physicochemical properties to control the drug release rate and interaction with cells in response to the surrounding environmental conditions or applied physical signals. The current review focuses on the strategy and availability of temperature-responsive (TR) polymeric micelles as a next-generation drug carrier. In particular, we discuss the unique properties of TR polymeric micelles, such as temperature-triggered drug release and intracellular uptake system. In addition, we explore the methodology for integrating other targeting systems into TR micelles to pursue the ideal pharmacodynamics in conjunction with thermal therapy as a future prospective of the TR system.

Thermally Controlled Intracellular Uptake System of Polymeric Micelles Possessing Poly(N-isopropylacrylamide)-Based Outer Coronas

Temperature-induced intracellular uptake mechanism of thermoresponsive polymeric micelles comprising poly(N-isopropylacrylamide-co-N,N-dimethylacrylamide)-b-poly(d,l-lactide) (P(IPAAm-DMAAm)-b-PLA) inside cultured bovine carotid endothelial cells is investigated by flow cytometry and confocal laser scanning microscopy. Hydrodynamic sizes of P(IPAAm-DMAAm)-b-PLA micelles are approximately 20 nm below the lower critical solution temperature (LCST) of 39.4 degrees C, and their sizes increased to ca. 600 nm above the LCST due to the aggregation of micelles. Intracellular uptake of P(IPAAm-DMAAm)-b-PLA micelles is significantly limited at a temperature below the micellar LCST, 37 degrees C. Of great interest, the P(IPAAm-DMAAm)-b-PLA micelles are internalized into the cells above the micellar LCST (42 degrees C), being dependent on polymer concentration, time, and temperature. By contrast, no intracellular uptake of polyethylene glycol-b-PLA micelles is observed regardless of temperature changes. Enhanced intracellular micelle uptake is probably due to the enhanced interactions between the micelles and cell membranes through the dehydration of corona-forming thermoresponsive polymer chains. Internalization of submicrometer-scale micellar aggregates inside the cells is probably due to their various endocytosis mechanisms. P(IPAAm-DMAAm)-b-PLA micelles localize at the Golgi apparatus and endoplasmic reticulum, but not inside lysosomes. These results indicate that the thermoresponsive polymeric micelles are greatly promising as intracellular delivery tools of drugs, nucleic acids, and peptides/protein without lysosomal decomposition in conjunction with applied heating.

Polymeric micelles with stimuli-triggering systems for advanced cancer drug targeting

Abstract Since the 1990s, nanoscale drug carriers have played a pivotal role in cancer chemotherapy, acting through passive drug delivery mechanisms and subsequent pharmaceutical action at tumor tissues with reduction of adverse effects. Polymeric micelles, as supramolecular assemblies of amphiphilic polymers, have been considerably developed as promising drug carrier candidates, and a number of clinical studies of anticancer drug-loaded polymeric micelle carriers for cancer chemotherapy applications are now in progress. However, these systems still face several issues; at present, the simultaneous control of target-selective delivery and release of incorporated drugs remains difficult. To resolve these points, the introduction of stimuli-responsive mechanisms to drug carrier systems is believed to be a promising approach to provide better solutions for future tumor drug targeting strategies. As possible trigger signals, biological acidic pH, light, heating/cooling and ultrasound actively play significant roles in signal-triggering drug release and carrier interaction with target cells. This review article summarizes several molecular designs for stimuli-responsive polymeric micelles in response to variation of pH, light and temperature and discusses their potentials as next-generation tumor drug targeting systems.

pH-induced phase transition control of thermoresponsive nano-micelles possessing outermost surface sulfonamide moieties

Diblock copolymer comprising thermoresponsive poly(N-isopropylacrylamide-co-N,N-dimethylacrylamide) (PIPAAm-co-DMAAm) and hydrophobic poly(benzyl methacrylate) blocks was prepared by reversible addition-fragmentation chain transfer radical polymerization. Terminal functionalization of thermoresponsive blocks with either pH-responsive sulfadimethoxine (SD) or hydroxyl groups was performed through coupling reactions with thiol groups exposed by the aminolysis of dithiobenzoate groups located at P(IPAAm-co-DMAAm) termini. Outermost surface functionalized polymeric micelles were formed through the multi-assemblies of end-functional diblock copolymers with low critical micelle concentration (3.1-3.3 mg/L) regardless of their terminal groups. Variety of outermost surface functional groups had little influence on nano-scale diameters of approximately 19 nm at various pH values. Although the zeta-potentials of nonionic (phenyl and hydroxyl) surface micelles were independent of pH values ranged 8.1-5.4, those of SD-surface polymeric micelles changed from -12 to -4 mV with reducing pH value, which caused by the protonation of surface SD units (pK(a)=6.2). In addition, lower critical solution temperature (LCST) of SD-surface micelles significantly shifted from 38.6 to 22.6 °C with lowering pH from 5.4 to 8.1. These pH-induced lower LCST shifts were caused by extremely increasing surface hydrophobicity through the charge neutralization of SD moieties and the subsequent promoted dehydration of corona-forming polymer chains. These results indicated that the phase transition behavior of thermoresponsive nano-micelles was particularly controlled by modulating the properties of outermost surface chemistry via specific signals (e.g., pH, light, and biomolecular interaction).

Facile cell sheet manipulation and transplantation by using in situ gelation method

Cell sheets harvested from temperature-responsive cell culture dishes (TRDs) has attracted considerable attention as effective tools for reconstructing the lost functions of tissues and organs in the regenerative medicine field. However, because of their thinness, handling problems sometimes arise when transferring cell sheets from a TRD to a target surface. In this study, we developed a facile cell transfer method referred to as in situ gelation by using both gelatin hydrogel and a support membrane. Gelation and low-temperature processes were simultaneously performed on TRD. Confluent cultured cells were efficiently harvested from TRD in less than 5 min by decreasing the incubation temperature to 20°C. Harvested cells were found to maintain their cell viability, extracellular matrix, and original shape, thus allowing transfer of the cells to another surface with a short incubation time at 37°C. This method is applicable for various cell types regardless of the formation of tight cell-cell junctions. In addition, because of the high flexibility of the gelatin-coated membrane, cells were efficiently transferred to the surface of a mouse subcutis and liver. When compared with conventional cell sheet manipulation methods, the interaction between the cell surface and membrane was reinforced by the uniformly formed gelatin gel layer without using a special device. Therefore, the in situ gelation method is a promising technique for cell sheet-based tissue engineering and regenerative medicine.

Transplantation of cancerous cell sheets effectively generates tumour-bearing model mice.

Tumour‐bearing mice were created by transplanting cancerous cell sheets onto the subcutaneous tissue of the dorsal region, using luciferase gene‐transfected mammary gland adenocarcinoma cells, 4T1‐luc2, to investigate the tumourigenicity of the cell sheet relative to a conventional injection of cell suspension. Contiguous breast cancerous cell sheets were harvested from temperature‐responsive culture dishes by reducing the temperature from 37 °C to 20 °C; the sheets were then transplanted onto the dorsal side of the mouse subcutaneous tissue, using a chitin‐based supporting membrane. Cell suspensions obtained by trypsin digestion were subcutaneously injected into the dorsal region of mice. The tumour growth of the transplanted cancer cells was evaluated by the tumour volume and by the bioluminescence from luciferase‐gene transfected cancer cells, using an in vivo imaging system. The cell sheet method improved the 4 T1‐luc2 engraftment efficiency in living mouse tissues at the initial stage by 13‐fold compared with that from injecting cell suspensions. On day 14 after the transplantation, the tumour formation at the transplanted area of cell sheet‐transplanted mice also accelerated, and the mean tumour volume became 1116 mm3, which was 10 times larger than that in cell suspension‐transplanted mice. The cell sheets engrafted on the recipient tissues efficiently due to the preserved extracellular matrix on their basal sides, such that cancer cells were supplied with sufficient oxygen and nutrients from the host tissues to develop tumour tissues. Therefore, cancerous cell sheet‐based transplantation is a promising method for efficiently creating cancer‐bearing mice. Copyright

Antibacterial Properties of Silver Nanoparticles Embedded on Polyelectrolyte Hydrogels Based on α-Amino Acid Residues

Polyelectrolyte hydrogels bearing l-phenylalanine (PHE), l-valine (AVA), and l-histidine (Hist) residues were used as scaffolds for the formation of silver nanoparticles by reduction of Ag+ ions with NaBH4. The interaction with the metal ion allowed a prompt collapse of the swollen hydrogel, due to the neutralization reaction of basic groups present on the polymer. The imidazole nitrogen of the hydrogel with Hist demonstrated greater complexing capacity with the Ag+ ion compared to the hydrogels with carboxyl groups. The subsequent reduction to metallic silver allowed for the restoration of the hydrogel’s degree of swelling to the starting value. Transmission electron microscopy (TEM) and spectroscopic analyses showed, respectively, a uniform distribution of the 15 nm spherical silver nanoparticles embedded on the hydrogel and peak optical properties around a wavelength of 400 nm due to the surface plasmonic effect. Unlike native hydrogels, the composite hydrogels containing silver nanoparticles showed good antibacterial activity as gram+/gram− bactericides, and higher antifungal activity against S. cerevisiae.