Nanomaterials show promising opportunities to address clinical problems (such as insufficient capture of circulating tumor cells; CTCs) via the high surface area-to-volume ratio and high affinity for biological cell...Nanomaterials show promising opportunities to address clinical problems (such as insufficient capture of circulating tumor cells; CTCs) via the high surface area-to-volume ratio and high affinity for biological cells. However, how to apply these nanomaterials as a nano-bio interface in a microfluidic device for efficient CTC capture with high specificity remains a challenge. In the present work, we first found that a titanium dioxide (TiO2) nanorod array that can be conveniently prepared on multiple kinds of substrates has high affinity for tumor cells. Then, the TiO2 nanorod array was vertically grown on the surface of a microchannel with hexagonally patterned Si micropillars via a hydrothermal reaction, forming a new kind of a micro-nano 3D hierarchically structured microfluidic device. The vertically grown TiO2 nanorod array was used as a sensitive nano-bio interface of this 3D hierarchically structured microfluidic device, which showed high efficiency of CTC capture (76.7% ± 7.1%) in an artificial whole-blood sample.展开更多
The field of two-dimensional(2D)nanomaterial-based cancer immunotherapy combines research from multiple subdisciplines of material science,nano-chemistry,in particular nanobiological interactions,immunology,and medici...The field of two-dimensional(2D)nanomaterial-based cancer immunotherapy combines research from multiple subdisciplines of material science,nano-chemistry,in particular nanobiological interactions,immunology,and medicinal chemistry.Most importantly,the"biological identity"of nanomaterials governed by bio-molecular corona in terms of bimolecular types,relative abundance,and conformation at the nanomaterial surface is now believed to influence blood circulation time,biodistribution,immune response,cellular uptake,and intracellular trafficking.A better understanding of nano-bio interactions can improve utilization of 2D nano-architectures for cancer immunotherapy and immunotheranostics,allowing them to be adapted or modified to treat other immune dysregulation syndromes including autoimmune diseases or inflammation,infection,tissue regeneration,and transplantation.The manuscript reviews the biological interactions and immunotherapeutic applications of 2D nanomaterials,including understanding their interactions with biological molecules of the immune system,summarizes and prospects the applications of 2D nanomaterials in cancer immunotherapy.展开更多
Carbonized polymer dots(CPDs)have been widely applied in biomedical fields,such as imaging,diagnosis and drug delivery.Since the complex,non-equilibrated and dynamic nature of biological systems inevitably affect the ...Carbonized polymer dots(CPDs)have been widely applied in biomedical fields,such as imaging,diagnosis and drug delivery.Since the complex,non-equilibrated and dynamic nature of biological systems inevitably affect the predesigned properties of CPDs,then efficiency and ultimate outcome of CPDs in biological identity will be transformed by the ubiquitous nano-bio interactions.Herein,our recent progress about elucidating the behavior of CPDs at nano-bio interface from the perspective of physical chemistry has been summarized in the review,mainly at the bio-macromolecular,cellular membrane and cellular levels,which is crucial for characterize their relative cytotoxicity and clinical transformation.Moreover,we mainly focused on the quantitative relationship of nano-bio interactions between CPDs with biological identity and related thermodynamics parameters during this process is also obtained from advanced isothermal titration calorimetry technique.Finally,our recent study about the photoluminescence origin is also included in this review,which favors modulating the photoluminescence of CPDs.展开更多
Understanding the interactions of nanomaterials(NMs) with biomolecules, organelles, cells, and organic tissues at the nano-bio interface can offer important information for their uptake, distribution, translocation, m...Understanding the interactions of nanomaterials(NMs) with biomolecules, organelles, cells, and organic tissues at the nano-bio interface can offer important information for their uptake, distribution, translocation, metabolism and degradation in vitro and in vivo, which can help to precisely tune and design "smart" NMs for biomedical applications. However, probing the interactions at the nano-bio interface, which generally requires dedicated analytical methods and tools, is remarkably complicated due to the dynamically changed nature of the nano-bio interface. Because of the advantages of high spatial resolution, high sensitivity, excellent accuracy, low matrix effects and non-destructiveness, synchrotron radiation(SR)-based analytical techniques have become extremely valuable tools. Herein, we present a comprehensive overview of SR-based techniques for the visualized study of NMs at cellular and subcellular interfaces and their transformation in vitro; the exploration of biodistribution, translocation, metabolism and degradation of NMs in vivo; and clarification of the molecular mechanisms of NMs' reactions with biomolecules. Rapid development of advanced light source means that in situ, real-time analysis of NMs at the nano-bio interface will be achieved.展开更多
Knowledge on the interactions between engineered nanomaterials(ENMs) and biological systems is critical both for the assessment of biological effects of ENMs and for the rational design of ENM-based products. However,...Knowledge on the interactions between engineered nanomaterials(ENMs) and biological systems is critical both for the assessment of biological effects of ENMs and for the rational design of ENM-based products. However, probing the events that occur at the nano-bio interface remains extremely challenging due to their complex and dynamic nature. So far, the understanding of mechanisms underlying nano-bio interactions has been mainly limited by the lack of proper analytical techniques with sufficient sensitivity, selectivity and resolution for characterization of nano-bio interface events. Moreover, many classic bioanalytical methods are not suitable for direct measurement of nano-bio interface interactions. These have made establishing analytical methodologies for systematic and comprehensive study of nano-bio interface one of the most focused areas in nanobiology. In this review we have discussed some representative developments regarding analytical techniques for nano-bio interface characterization, including the improvements of traditional methods and the emergence of powerful new technologies. These developments have allowed ultrasensitive, real-time analysis of interactions between ENMs and biomolecules, transformations of ENMs in biological environment, and impacts of ENMs on living systems on molecular or cellular level.展开更多
With the rapid development of nanoscience and nanotechnology, more engineered nanomaterials(NMs) are being released into the environment. Such releases might lead to unwanted exposure. The dissolution of NMs at nano-b...With the rapid development of nanoscience and nanotechnology, more engineered nanomaterials(NMs) are being released into the environment. Such releases might lead to unwanted exposure. The dissolution of NMs at nano-bio interfaces is one of the most noteworthy causes of the toxicity of dissolvable NMs. A growing number of studies are focusing assessing NMs dissolution during exposure tests. This mini review considers recent developments in the quantitative tools for the assessment of NMs dissolution, and highlights the critical points in the evaluation of the toxicity of dissolvable NMs.展开更多
Two-dimensional(2D)nanomaterials,known for their unique atomic arrangements and exceptional physicochemical properties,have garnered significant attention in biomedical applications,particularly in the realms of immun...Two-dimensional(2D)nanomaterials,known for their unique atomic arrangements and exceptional physicochemical properties,have garnered significant attention in biomedical applications,particularly in the realms of immunotherapy for tissue engineering and tumor therapy.These applications necessitate a thorough assessment of the potential influence of 2D nanomaterials on immune cells.Notably,the mononuclear phagocyte system(MPS)cells,which play pivotal roles in both innate and adaptive immunity,are essential for maintaining organismal homeostasis.MPS cells with phagocytic capability contribute to the prevention of foreign body invasion and the elimination of dead or senescent cells.Furthermore,MPS cells,including macrophages and dendritic cells,serve as vital bridges between innate and adaptive immune responses.Therefore,understanding the nano-bio interactions between 2D nanomaterials and MPS cells is imperative.These nano-bio interactions including cellular uptake,cytocompatibility,and immunological impact are invaluable forthe purposeful design of 2D nanomaterials.Herein,we provide an overview of the latest advancements in understanding the nano-bio interactions between 2D nanomaterials and MPS cells,and discuss the current challenges and future prospects of employing 2D nanomaterials in the field of nanomedicine.展开更多
Research in biology and medicine is a rapidly expanding field incorporating some of the most fundamental questions concerning structure, function, and purpose. The forefront of new research demands access to advanced ...Research in biology and medicine is a rapidly expanding field incorporating some of the most fundamental questions concerning structure, function, and purpose. The forefront of new research demands access to advanced techniques and instrumentation capable of probing these unanswered questions. Over the past several decades, nano-scale materials and devices ranging from quasione dimensional quantum dots to two dimensional graphene sheets have been engineered and have found applications in nano-bio imaging and spectroscopy. In this review, the incorporation of nanomaterials into three influential spectroscopic and microscopic techniques including fluorescence microscopy, surface plasmon resonance, and sum frequency generation will be introduced. Fluorescence imaging has visualized nanomaterials as compliments or replacements to comparable organic fluorphores, act as a quencher for FRET-based sensing, and serve as a nanoscaffold for molecular beacons. Their versatility in coating materials makes nanomaterials an excellent targeting molecule for any cellular macromolecule or structure. In addition to the targeting capabilities of nanomaterials in fluorescence imaging, surface plasmon resonance has incorporated nanomaterials for applications in signal enhancement, selectivity of target molecules, and the development of more refined and accurate detection. Functionalized nano-particles enhance the capabilities of sum frequency generation vibrational spectroscopy by providing unique surface chemistry which alters target molecule interactions and orientations. In summary, the incorporation of nanomaterials has greatly enhanced the field of biology and medicine and has allowed for the continual advancement of not only research but instrument development.展开更多
基金The authors are thankful for funding from the National Natural Science Foundation of China (Nos. 51402063, 51432005, 61405040, 61505010, 51502018, 31270022, and 81471784), the "100 Talents Program" of the Chinese Academy of Sciences, Beijing City Committee of science and technology (No. Z151100003315010), Beijing Natural Science Foundation (Nos. 2164077 and 2164076), the Fundamental Research Funds of Shandong University (No. 2014QY003), and the Youth Innovation Promotion Association of the Chinese Academy of Sciences (No. 2015023). The authors also acknowledge the support from the"thousands talents" program for pioneer researchers and his innovation team, and support from the President Funding of the Chinese Academy of Sciences.
文摘Nanomaterials show promising opportunities to address clinical problems (such as insufficient capture of circulating tumor cells; CTCs) via the high surface area-to-volume ratio and high affinity for biological cells. However, how to apply these nanomaterials as a nano-bio interface in a microfluidic device for efficient CTC capture with high specificity remains a challenge. In the present work, we first found that a titanium dioxide (TiO2) nanorod array that can be conveniently prepared on multiple kinds of substrates has high affinity for tumor cells. Then, the TiO2 nanorod array was vertically grown on the surface of a microchannel with hexagonally patterned Si micropillars via a hydrothermal reaction, forming a new kind of a micro-nano 3D hierarchically structured microfluidic device. The vertically grown TiO2 nanorod array was used as a sensitive nano-bio interface of this 3D hierarchically structured microfluidic device, which showed high efficiency of CTC capture (76.7% ± 7.1%) in an artificial whole-blood sample.
基金support from the US METAvivor Early Career Investigator Award(No.2018A020560,Wei Tao,USA)Harvard Medical School/Brigham and Women’s Hospital Department of Anesthesiology-Basic Scientist Grant(No.2420 BPA075,Wei Tao,USA)+3 种基金Center for Nanomedicine Research Fund(NO.2019A014810,Wei Tao,USA)supported by The Hundred Talents Program,China(75110-18841227)from Sun Yat-Sen University,Guangzhou,Chinathe Guangdong Basic and Applied Basic Research Foundation(2019A1515110326,China)supported by the China postdoctoral science foundation(2019M663060)。
文摘The field of two-dimensional(2D)nanomaterial-based cancer immunotherapy combines research from multiple subdisciplines of material science,nano-chemistry,in particular nanobiological interactions,immunology,and medicinal chemistry.Most importantly,the"biological identity"of nanomaterials governed by bio-molecular corona in terms of bimolecular types,relative abundance,and conformation at the nanomaterial surface is now believed to influence blood circulation time,biodistribution,immune response,cellular uptake,and intracellular trafficking.A better understanding of nano-bio interactions can improve utilization of 2D nano-architectures for cancer immunotherapy and immunotheranostics,allowing them to be adapted or modified to treat other immune dysregulation syndromes including autoimmune diseases or inflammation,infection,tissue regeneration,and transplantation.The manuscript reviews the biological interactions and immunotherapeutic applications of 2D nanomaterials,including understanding their interactions with biological molecules of the immune system,summarizes and prospects the applications of 2D nanomaterials in cancer immunotherapy.
基金the Nation-al Key R&D Program of China(2018FYA0703700)the National Natural Science Foundation of China(21873075,21603067)+2 种基金Guangxi Science and Technology Project(GuiKeAD17195081)Bagui Scholar Program of Guangxi Province(2016)Hubei Na-ture Science Foundation of China(2019CFB748).
文摘Carbonized polymer dots(CPDs)have been widely applied in biomedical fields,such as imaging,diagnosis and drug delivery.Since the complex,non-equilibrated and dynamic nature of biological systems inevitably affect the predesigned properties of CPDs,then efficiency and ultimate outcome of CPDs in biological identity will be transformed by the ubiquitous nano-bio interactions.Herein,our recent progress about elucidating the behavior of CPDs at nano-bio interface from the perspective of physical chemistry has been summarized in the review,mainly at the bio-macromolecular,cellular membrane and cellular levels,which is crucial for characterize their relative cytotoxicity and clinical transformation.Moreover,we mainly focused on the quantitative relationship of nano-bio interactions between CPDs with biological identity and related thermodynamics parameters during this process is also obtained from advanced isothermal titration calorimetry technique.Finally,our recent study about the photoluminescence origin is also included in this review,which favors modulating the photoluminescence of CPDs.
基金supported by the National Basic Research Program of China(2011CB933403)the State Key Program of National Natural Science Foundation of China(U1432245)the National Natural Science Foundation of China(11475195,11275214,11375211)
文摘Understanding the interactions of nanomaterials(NMs) with biomolecules, organelles, cells, and organic tissues at the nano-bio interface can offer important information for their uptake, distribution, translocation, metabolism and degradation in vitro and in vivo, which can help to precisely tune and design "smart" NMs for biomedical applications. However, probing the interactions at the nano-bio interface, which generally requires dedicated analytical methods and tools, is remarkably complicated due to the dynamically changed nature of the nano-bio interface. Because of the advantages of high spatial resolution, high sensitivity, excellent accuracy, low matrix effects and non-destructiveness, synchrotron radiation(SR)-based analytical techniques have become extremely valuable tools. Herein, we present a comprehensive overview of SR-based techniques for the visualized study of NMs at cellular and subcellular interfaces and their transformation in vitro; the exploration of biodistribution, translocation, metabolism and degradation of NMs in vivo; and clarification of the molecular mechanisms of NMs' reactions with biomolecules. Rapid development of advanced light source means that in situ, real-time analysis of NMs at the nano-bio interface will be achieved.
基金supported by the National Natural Science Foundation of China (21320102003, 31200752, 31661130152, 11435002)the National Distinguished Young Scientists Program (31325010)
文摘Knowledge on the interactions between engineered nanomaterials(ENMs) and biological systems is critical both for the assessment of biological effects of ENMs and for the rational design of ENM-based products. However, probing the events that occur at the nano-bio interface remains extremely challenging due to their complex and dynamic nature. So far, the understanding of mechanisms underlying nano-bio interactions has been mainly limited by the lack of proper analytical techniques with sufficient sensitivity, selectivity and resolution for characterization of nano-bio interface events. Moreover, many classic bioanalytical methods are not suitable for direct measurement of nano-bio interface interactions. These have made establishing analytical methodologies for systematic and comprehensive study of nano-bio interface one of the most focused areas in nanobiology. In this review we have discussed some representative developments regarding analytical techniques for nano-bio interface characterization, including the improvements of traditional methods and the emergence of powerful new technologies. These developments have allowed ultrasensitive, real-time analysis of interactions between ENMs and biomolecules, transformations of ENMs in biological environment, and impacts of ENMs on living systems on molecular or cellular level.
文摘With the rapid development of nanoscience and nanotechnology, more engineered nanomaterials(NMs) are being released into the environment. Such releases might lead to unwanted exposure. The dissolution of NMs at nano-bio interfaces is one of the most noteworthy causes of the toxicity of dissolvable NMs. A growing number of studies are focusing assessing NMs dissolution during exposure tests. This mini review considers recent developments in the quantitative tools for the assessment of NMs dissolution, and highlights the critical points in the evaluation of the toxicity of dissolvable NMs.
基金National Key Research and Development Program of China,Grant/Award Numbers:2022YFB3203800,2022YFB3203801,2022YFB3203804CAS Interdisciplinary Innovation Team,Grant/Award Number:JCTD-2020-08+6 种基金Innovative Research Team of High-Level Local Universities in Shanghai,Grant/Award Number:SHSMU-ZDCX20210900Zhejiang Provincial Natural Science Foundation of China,Grant/Award Number:LR22C100001National Natural Science Foundation of China,Grant/Award Number:32071374Shanghai Municipal Science and Technology Commission,Grant/Award Number:21dz2210100Explorer Program of Science and Technology Commission of Shanghai Municipality,Grant/Award Number:22TS1400700Start-Up Funds from Shanghai Jiao Tong University,Grant/Award Number:22X010201631Program of Shanghai Academic Research Leader under the Science and Technology Innovation Action Plan,Grant/Award Number:21XD1422100。
文摘Two-dimensional(2D)nanomaterials,known for their unique atomic arrangements and exceptional physicochemical properties,have garnered significant attention in biomedical applications,particularly in the realms of immunotherapy for tissue engineering and tumor therapy.These applications necessitate a thorough assessment of the potential influence of 2D nanomaterials on immune cells.Notably,the mononuclear phagocyte system(MPS)cells,which play pivotal roles in both innate and adaptive immunity,are essential for maintaining organismal homeostasis.MPS cells with phagocytic capability contribute to the prevention of foreign body invasion and the elimination of dead or senescent cells.Furthermore,MPS cells,including macrophages and dendritic cells,serve as vital bridges between innate and adaptive immune responses.Therefore,understanding the nano-bio interactions between 2D nanomaterials and MPS cells is imperative.These nano-bio interactions including cellular uptake,cytocompatibility,and immunological impact are invaluable forthe purposeful design of 2D nanomaterials.Herein,we provide an overview of the latest advancements in understanding the nano-bio interactions between 2D nanomaterials and MPS cells,and discuss the current challenges and future prospects of employing 2D nanomaterials in the field of nanomedicine.
文摘Research in biology and medicine is a rapidly expanding field incorporating some of the most fundamental questions concerning structure, function, and purpose. The forefront of new research demands access to advanced techniques and instrumentation capable of probing these unanswered questions. Over the past several decades, nano-scale materials and devices ranging from quasione dimensional quantum dots to two dimensional graphene sheets have been engineered and have found applications in nano-bio imaging and spectroscopy. In this review, the incorporation of nanomaterials into three influential spectroscopic and microscopic techniques including fluorescence microscopy, surface plasmon resonance, and sum frequency generation will be introduced. Fluorescence imaging has visualized nanomaterials as compliments or replacements to comparable organic fluorphores, act as a quencher for FRET-based sensing, and serve as a nanoscaffold for molecular beacons. Their versatility in coating materials makes nanomaterials an excellent targeting molecule for any cellular macromolecule or structure. In addition to the targeting capabilities of nanomaterials in fluorescence imaging, surface plasmon resonance has incorporated nanomaterials for applications in signal enhancement, selectivity of target molecules, and the development of more refined and accurate detection. Functionalized nano-particles enhance the capabilities of sum frequency generation vibrational spectroscopy by providing unique surface chemistry which alters target molecule interactions and orientations. In summary, the incorporation of nanomaterials has greatly enhanced the field of biology and medicine and has allowed for the continual advancement of not only research but instrument development.
