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BACKGROUND:Near infrared responsive hydrogels,have a variety of excellent properties such as high spatial and temporal precision,remote tunability,and safety and non-invasiveness,providing a new direction of exploration for the development of tissue engineering. OBJECTIVE:To summarize the application progress of near infrared responsive hydrogels in the field of tissue engineering in recent years. METHODS:The literature search was performed on PubMed and CNKI databases.The keywords were"near infrared responsive hydrogels,tissue engineering,bone defect,bone repair,bone regeneration,wound healing,wound dressing,angiogenesis"in Chinese and English.The search time limit was from May 2006 to October 2022 and extended for some classical literature.The abstracts and contents of the retrieved literature were analyzed,and the relevant literature was obtained according to inclusion and exclusion criteria.Finally,97 articles were included for review. RESULTS AND CONCLUSION:(1)Near infrared responsive materials are involved in tissue repair by controlling infection and reducing inflammation,promoting angiogenesis,osteoblast differentiation and new bone formation.(2)Near infrared responsive hydrogel can be prepared by constructing a thermosensitive hydrogel with a photothermal effect or by using a photochemical reaction.(3)Near infrared responsive hydrogels as wound dressings perform various functions such as rapid hemostasis,tissue adhesion through polymerization of polymer monomers,antibacterial and anti-inflammatory effects,and promotion of angiopoiesis and epithelial regeneration through the local photothermal effect of photothermal nanomaterials during soft tissue healing and regeneration.(4)Near infrared responsive hydrogels function during bone reconstruction and repair by promoting osteogenic differentiation of mesenchymal stem cells,stimulating the expression of heat shock proteins,and increasing angiogenesis.(5)Near infrared responsive hydrogels present a combination of multiple therapeutic strategies with significant synergistic therapeutic functions and are also being progressively developed for application in other tissue reconstruction and disease treatment scenarios.
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Objective To avoid the accumulation of copper sulfide (CuS) nanoparticles, prepare and optimize CuS nanoparticles, analyze the factors affecting the particle size and evaluate their photothermal properties. Methods Based on the single factor study, central composite design-response surface methodology was used to optimize the CuS nanoparticle formulation process. The morphology, particle size stability, photothermal conversion efficiency, photothermal stability of optimized CuS nanoparticles were characterized. The toxicity of CuS nanoparticles on 4T1 breast cancer cells and HK2 kidney cells was evaluated by CCK-8 method. In vitro photothermal experiment was used to investigate the ability of CuS nanoparticles on killing 4T1 breast cancer cells. Results The average hydration dynamic diameter of optimized CuS nanoparticles was (10.53±1.63)nm, the actual particle size of CuS nanoparticles showed by TEM image was (3.10±0.81)nm. It had good particle size stability, good photothermal conversion efficiency and photothermal stability. Within the concentration range of 100 μg/ml and 150 μg/ml,it showed no significant toxicity on 4T1 breast cancer cells and HK2 kidney cells, indicating the good stability of CuS nanoparticles. In vitro photothermal therapy showed that CuS nanoparticles had good ability to kill 4T1 breast cancer cells by photothermal. Conclusion The prepared CuS nanoparticles have a small particle size (less than 6nm) and a good photothermal effect, which is expected to solve the problem of CuS nanoparticles accumulation in vivo and make it better for tumor treatment.
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OBJECTIVE: To prepare Adriamycin hydrochloride (DOX) magnetic thermosensitive liposome (MTSL), investigate its physicochemical properties, magnetic effect and photothermal effect, so as to provide reference for tumor chemo- therapy and photodynamic/photothermal therapy. METHODS: Using DOX as model drug, TiO2@Fe3O4 as photosensitizers and magnetic materials, DOX-TiO2@Fe3O4-MTSL was prepared with membrane dispersion method. The morphology and dispersibility were observed; particle size and Zeta potential were detected; encapsulation efficiency of the liposome were determined by centrifugal ultrafiltration and HPLC. Its paramagnetism property was also detected by magnetometer. Compared with DOX solution, in vitro release behavior of the liposome was investigated by dialysis method, and the release curves at different temperatures (at 37, 43 ℃) were compared. The photothermal conversion effect of the liposome and the production of reactive oxygen species (ROS) in human breast cancer MCF-7 cells were investigated by near infrared laser irradiation at 808 nm. RESULTS: Prepared DOX-TiO2@Fe3O4-MTSL was brown-black with good water dispersion, and was spherical in shape and uniform in size under electron microscopy. Average particle size was 250.6 nm; polydispersity index was 0.107; Zeta potential was (-7.76±3.41)mV; encapsulation efficiency was (92.3±3.2)%. Under the external magnetic field, the liposome could move in a directional direction and had obvious paramagnetism. Compared with DOX solution, the liposomes released slowly and showed obvious sustained- release characteristics. Compared with at 37 ℃, the drug release of liposome speeded up significantly at 43 ℃.With the increase of laser (808 nm) irradiation time, the temperature of the liposome kept rising, which had obvious photothermal conversion effect and could induce the increase of ROS in MCF-7 cells. CONCLUSIONS: DOX-TiO2@Fe3O4-MTSL is prepared succe- ssfully, which has uniform appearance, good physical and chemical properties. It has obvious paramagnetism sustained release effect and photothermal conversion efficiency, and can promote ROS production in MCF-7 cells under near infrared laser irradiation at 808 nm.