The therapeutic efficiency of sonodynamic therapy(SDT)mainly depends on the presence of oxygen(O_(2))to generate harmful reactive oxygen species(ROS);thus,the hypoxic tumor microenvironment significantly limits the ef...The therapeutic efficiency of sonodynamic therapy(SDT)mainly depends on the presence of oxygen(O_(2))to generate harmful reactive oxygen species(ROS);thus,the hypoxic tumor microenvironment significantly limits the efficacy of SDT.Therefore,the development of oxygen-independent free radical generators and associated combination therapy tactics can be a promising field to facilitate the anticancer capability of SDT.In this study,a biomimetic drug delivery system(C-TiO_(2)/AIPH@PM)composed of an alkyl-radical generator(2,2′-azobis[2-(2-imidazolin-2-yl)propane]dihydrochloride,AIPH)-loaded C-TiO_(2) hollow nanoshells(HNSs)as the inner cores,and a platelet membrane(PM)as the outer shells is successfully prepared for synergistic SDT and oxygen-independent alkyl-radical therapy.The PM encapsulation can significantly prolong the blood circulation time of CTiO_(2)/AIPH@PM compared with C-TiO_(2)/AIPH while enabling C-TiO_(2)/AIPH@PM to achieve tumor targeting.C-TiO_(2)/AIPH@PM can efficiently produce ROS and alkyl radicals,which can achieve a more thorough tumor eradication regardless of the normoxic or hypoxic conditions.Furthermore,the generation of these radicals improves the efficiency of SDT.In addition,nitrogen(N_(2))produced due to the decomposition of AIPH enhances the acoustic cavitation effect and lowers the cavitation threshold,thereby enhancing the penetration of CTiO_(2)/AIPH@PM at the tumor sites.Both in vitro and in vivo experiments demonstrate that CTiO_(2)/AIPH@PM possesses good biosafety,ultrasound imaging performance,and excellent anticancer efficacy.This study provides a new strategy to achieve oxygen-independent free radical production and enhance therapeutic efficacy by combining SDT and free radical therapy.展开更多
Reconfigurable manufacturing systems (RMSs), which possess the advantages of both dedicated serial lines and flexible manufacturing systems, were introduced in the mid-1990s to address the challenges initiated by gl...Reconfigurable manufacturing systems (RMSs), which possess the advantages of both dedicated serial lines and flexible manufacturing systems, were introduced in the mid-1990s to address the challenges initiated by globalization. The principal goal of an RMS is to enhance the responsiveness of manufacturing systems to unforeseen changes in product demand. RMSs are cost- effective because they boost productivity, and increase the lifetime of the manufacturing system. Because of the many streams in which a product may be produced on an RMS, maintaining product precision in an RMS is a challenge. But the experience with RMS in the last 20 years indicates that product quality can be definitely maintained by inserting in-line inspection stations. In this paper, we formulate the design and operational principles for RMSs, and provide a state-of-the-art review of the design and operations methodologies of RMSs according to these principles. Finally, we propose future research directions, and deliberate on how recent intelligent manufacturing technologies may advance the design and operations of RMSs.展开更多
基金This work was supported by the Research fund of Anhui Institute of Translation Medicine(No.2021zhyx-C49)the Foundation of Anhui Medical University(No.2021xkj030)+2 种基金the Anhui Provincial Natural Science Foundation(No.2208085QC81)the Basic and Clinical Cooperative Research and Promotion Program of Anhui Medical University(No.2021xkjT028)Grants for Scientific Research of BSKY from Anhui Medical University(No.1406012201).
文摘The therapeutic efficiency of sonodynamic therapy(SDT)mainly depends on the presence of oxygen(O_(2))to generate harmful reactive oxygen species(ROS);thus,the hypoxic tumor microenvironment significantly limits the efficacy of SDT.Therefore,the development of oxygen-independent free radical generators and associated combination therapy tactics can be a promising field to facilitate the anticancer capability of SDT.In this study,a biomimetic drug delivery system(C-TiO_(2)/AIPH@PM)composed of an alkyl-radical generator(2,2′-azobis[2-(2-imidazolin-2-yl)propane]dihydrochloride,AIPH)-loaded C-TiO_(2) hollow nanoshells(HNSs)as the inner cores,and a platelet membrane(PM)as the outer shells is successfully prepared for synergistic SDT and oxygen-independent alkyl-radical therapy.The PM encapsulation can significantly prolong the blood circulation time of CTiO_(2)/AIPH@PM compared with C-TiO_(2)/AIPH while enabling C-TiO_(2)/AIPH@PM to achieve tumor targeting.C-TiO_(2)/AIPH@PM can efficiently produce ROS and alkyl radicals,which can achieve a more thorough tumor eradication regardless of the normoxic or hypoxic conditions.Furthermore,the generation of these radicals improves the efficiency of SDT.In addition,nitrogen(N_(2))produced due to the decomposition of AIPH enhances the acoustic cavitation effect and lowers the cavitation threshold,thereby enhancing the penetration of CTiO_(2)/AIPH@PM at the tumor sites.Both in vitro and in vivo experiments demonstrate that CTiO_(2)/AIPH@PM possesses good biosafety,ultrasound imaging performance,and excellent anticancer efficacy.This study provides a new strategy to achieve oxygen-independent free radical production and enhance therapeutic efficacy by combining SDT and free radical therapy.
文摘Reconfigurable manufacturing systems (RMSs), which possess the advantages of both dedicated serial lines and flexible manufacturing systems, were introduced in the mid-1990s to address the challenges initiated by globalization. The principal goal of an RMS is to enhance the responsiveness of manufacturing systems to unforeseen changes in product demand. RMSs are cost- effective because they boost productivity, and increase the lifetime of the manufacturing system. Because of the many streams in which a product may be produced on an RMS, maintaining product precision in an RMS is a challenge. But the experience with RMS in the last 20 years indicates that product quality can be definitely maintained by inserting in-line inspection stations. In this paper, we formulate the design and operational principles for RMSs, and provide a state-of-the-art review of the design and operations methodologies of RMSs according to these principles. Finally, we propose future research directions, and deliberate on how recent intelligent manufacturing technologies may advance the design and operations of RMSs.
