Brain,the material foundation of human intelligence,is the most complex tissue in the human body.Brain diseases are among the leading threats to human life,yet our understanding of their pathogenic mechanisms and drug...Brain,the material foundation of human intelligence,is the most complex tissue in the human body.Brain diseases are among the leading threats to human life,yet our understanding of their pathogenic mechanisms and drug development remains limited,largely due to the lack of accurate brain-like tissue models that replicate its complex structure and functions.Therefore,constructing brain-like models—both in morphology and function—possesses significant scientific value for advancing brain science and pathological pharmacology research,representing the frontiers in the biomanufacturing field.This review outlines the primary requirements and challenges in biomanufacturing brain-like tissue,addressing its complex structures,functions,and environments.Also,the existing biomanufacturing technologies,strategies,and characteristics for brain-like models are depicted,and cutting-edge developments in biomanufacturing central neural repair prosthetics,brain development models,brain disease models,and brain-inspired biocomputing models are systematically reviewed.Finally,the paper concludes with future perspectives on the biomanufacturing of brain-like tissue transitioning from structural manufacturing to intelligent functioning.展开更多
Three-dimensional(3D)bioprinting provides a rapid and efficient method for fabricating customized bioprinted tissues that replicate the complex architecture of native tissues.However,in 3D bioprinting,the need for den...Three-dimensional(3D)bioprinting provides a rapid and efficient method for fabricating customized bioprinted tissues that replicate the complex architecture of native tissues.However,in 3D bioprinting,the need for dense biomaterial networks to ensure mechanical strength and structural fidelity often restricts the spreading,migration,and proliferation of encapsulated cells,as well as the transport of materials.This review summarizes effective strategies for manufacturing microporous bioprinted tissues via 3D bioprinting.The term“microporous”refers to interconnected,micrometer-sized pore-like structures within the internal materials of bioprinted tissues,including the microstructure of a single extruded fiber in extrusion printing.This differs from the macroscopic pore structure formed between fibers composed of print tracks or computer-aided design presets.These micropores play a crucial role in advancing biomanufacturing and 3D bioprinting by providing space for cell adhesion and proliferation while facilitating the timely transport of nutrients and metabolic waste essential for cell growth.Additionally,microporous bioprinted tissues offer the mechanical support needed for cell seeding and serve as sites for extracellular matrix deposition.As microporous 3D bioprinting continues to advance,it has the potential to address unresolved challenges in fields such as organ transplantation,tissue regeneration,and tissue replacement.展开更多
Animal models have been extensively used in cancer pathology studies and drug discovery.These models,however,fail to reflect the complex human tumor microenvironment and do not allow for high-throughput drug screening...Animal models have been extensively used in cancer pathology studies and drug discovery.These models,however,fail to reflect the complex human tumor microenvironment and do not allow for high-throughput drug screening in more human-like physiological conditions.Three-dimensional(3D)cancer models present an alternative to automated high-throughput cancer drug discovery and oncology.In this review,we highlight recent technology innovations in building 3D tumor models that simulate the complex human tumor microenvironment and responses of patients to treatment.We discussed various biofabrication technologies,including 3D bioprinting techniques developed for characterizing tumor progression,metastasis,and response to treatment.展开更多
Technological and economic opportunities,alongside the apparent ecological benefits,point to biodesign as a new industrial paradigm for the fabrication of products in the twenty-first century.The presented work studie...Technological and economic opportunities,alongside the apparent ecological benefits,point to biodesign as a new industrial paradigm for the fabrication of products in the twenty-first century.The presented work studies plant roots as a biodesign material in the fabrication of self-supported 3D structures,where the biologically and digitally designed materials provide each other with structural stability.Taking a material-driven design approach,we present our systematic tinkering activities with plant roots to better understand and anticipate their responsive behaviour.These helped us to identify the key design parameters and advance the unique potential of plant roots to bind discrete porous structures.We illustrate this binding potential of plant roots with a hybrid 3D object,for which plant roots connect 600 computationally designed,optimized,and fabricated bioplastic beads into a low stool.展开更多
Biofabrication,also known as bioprinting,has been widely used in the field of biomedicine.The three most important factors in biofabrication are 3D bioprinter,biomaterials to be printed(bioinks),and the printing objec...Biofabrication,also known as bioprinting,has been widely used in the field of biomedicine.The three most important factors in biofabrication are 3D bioprinter,biomaterials to be printed(bioinks),and the printing object(application).This review provides a detailed introduction to the latest research progress in these aspects.In particularly,the bioinks for bioprinting require strict biocompatible requirements.Four typical materials,i.e.metal/alloys,ceramics,polymers,and their composites,were introduced in detail,and their printing process and application scenarios were summarized,respectively.There are many applications of biofabrication in clinical practice.The application of biofabrication in skeletal system,skin and soft tissue,cardiovascular system,digestive system,respiratory system,urinary system,nervous system,plastic surgery and medical aesthetics were briefly introduced.The applications of biofabrication has a wide range of clinical need.Biofabrication is an innovative technology that is expected to further promote the clinical precision treatments.展开更多
Objective:To formulate a simple rapid procedure for bioreduction of silver nanoparticles using aqueous leaves extract of Moringa oleifera(M.oleifera).Methods:10 mL of leaf extract was mixed to 90 mL of 1 mM aqueous of...Objective:To formulate a simple rapid procedure for bioreduction of silver nanoparticles using aqueous leaves extract of Moringa oleifera(M.oleifera).Methods:10 mL of leaf extract was mixed to 90 mL of 1 mM aqueous of AgNO_3 and was heated at 60-80 ℃ for 20 min.A change from brown to reddish color was observed.Characterization using UV-Vis spectrophotometry, Transmission Electron Microscopy(TEM) was performed.Results:TEM showed the formation of silver nanoparticles with an average size of 57 nm.Conclusions:M.oleifera demonstrates strong potential for synthesis of silver nanoparticles by rapid reduction of silver ions(Ag^+ to Ag^0). Biological methods are good competents for the chemical procedures,which are eco-friendly and convenient.展开更多
While traditional bulk hydrogels have been widely used in 3D bioprinting for tissue engineering,engineered cell-loaded scaffolds still fall short of expectations because their nanoscale molecular networks impede cell ...While traditional bulk hydrogels have been widely used in 3D bioprinting for tissue engineering,engineered cell-loaded scaffolds still fall short of expectations because their nanoscale molecular networks impede cell function.Microgels,as micronsized hydrogel materials,offer significant advantages in enhancing mass transport and tissue permeability,while concurrently promoting cellular proliferation,migration,and differentiation.Incorporating microgels as bioinks into 3D bioprinting enables customization of shape,mechanical properties,and functionality,significantly expanding the applications of hydrogel materials and addressing diverse bioprinting needs.Hierarchically porous scaffolds formed by microgel assembly leverage dual-scale porosity:nanoporosity inherent in the material and microporosity originating from the assembly.This unique structure promotes tissue regeneration and facilitates microtissue assembly.This review provides an overview of microgel fabrication techniques,describing their role as carriers for cells and biomolecules,as well as their applications in 3D biofabrication.Notably,we throughout present the application of microgels in 3D biofabrication.Finally,we provide an outlook on the potential applications of microgels in biomedical engineering and their integration with emerging printing technologies.展开更多
In the human body,almost all cells interact with extracellular matrices(ECMs),which have tissue and organ-specific compositions and architectures.These ECMs not only function as cellular scaffolds,providing structural...In the human body,almost all cells interact with extracellular matrices(ECMs),which have tissue and organ-specific compositions and architectures.These ECMs not only function as cellular scaffolds,providing structural support,but also play a crucial role in dynamically regulating various cellular functions.This comprehensive review delves into the examination of biofabrication strategies used to develop bioactive materials that accurately mimic one or more biophysical and biochemical properties of ECMs.We discuss the potential integration of these ECM-mimics into a range of physiological and pathological in vitro models,enhancing our understanding of cellular behavior and tissue organization.Lastly,we propose future research directions for ECM-mimics in the context of tissue engineering and organ-on-a-chip applications,offering potential advancements in therapeutic approaches and improved patient outcomes.展开更多
There is a high demand for bespoke grafts to replace damaged or malformed bone and cartilage tissue.Three-dimensional(3D)printing offers a method of fabricating complex anatomical features of clinically relevant sizes...There is a high demand for bespoke grafts to replace damaged or malformed bone and cartilage tissue.Three-dimensional(3D)printing offers a method of fabricating complex anatomical features of clinically relevant sizes.However,the construction of a scaffold to replicate the complex hierarchical structure of natural tissues remains challenging.This paper reports a novel biofabrication method that is capable of creating intricately designed structures of anatomically relevant dimensions.The beneficial properties of the electrospun fibre meshes can finally be realised in 3D rather than the current promising breakthroughs in two-dimensional(2D).The 3D model was created from commercially available computer-aided design software packages in order to slice the model down into many layers of slices,which were arrayed.These 2D slices with each layer of a defined pattern were laser cut,and then successfully assembled with varying thicknesses of 100μm or 200μm.It is demonstrated in this study that this new biofabrication technique can be used to reproduce very complex computer-aided design models into hierarchical constructs with micro and nano resolutions,where the clinically relevant sizes ranging from a simple cube of 20 mm dimension,to a more complex,50 mm-tall human ears were created.In-vitro cell-contact studies were also carried out to investigate the biocompatibility of this hierarchal structure.The cell viability on a micromachined electrospun polylactic-co-glycolic acid fibre mesh slice,where a range of hole diameters from 200μm to 500μm were laser cut in an array where cell confluence values of at least 85%were found at three weeks.Cells were also seeded onto a simpler stacked construct,albeit made with micromachined poly fibre mesh,where cells can be found to migrate through the stack better with collagen as bioadhesives.This new method for biofabricating hierarchical constructs can be further developed for tissue repair applications such as maxillofacial bone injury or nose/ear cartilage replacement in the future.展开更多
A self-hardening three-dimensional(3D)-porous composite bone graft consisting of 65 wt%hydroxyapatite(HA)and 35 wt%aragonite was fabricated using a 3D-Bioplotter®.New tetracalcium phosphate and dicalcium phosphat...A self-hardening three-dimensional(3D)-porous composite bone graft consisting of 65 wt%hydroxyapatite(HA)and 35 wt%aragonite was fabricated using a 3D-Bioplotter®.New tetracalcium phosphate and dicalcium phosphate anhydrous/aragonite/gelatine paste formulae were developed to overcome the phase separation of the liquid and solid components.The mechanical properties,porosity,height and width stability of the end products were optimised through a systematic analysis of the fabrication processing parameters including printing pressure,printing speed and distance between strands.The resulting 3D-printed bone graft was confirmed to be a mixture of HA and aragonite by X-ray diffraction,Fourier transform infrared spectroscopy and energy dispersive X-ray spectroscopy.The compression strength of HA/aragonite was between 0.56 and 2.49 MPa.Cytotoxicity was assessed using the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide(MTT)assay in vitro.The osteogenicity of HA/aragonite was evaluated in vitro by alkaline phosphatase assay using human umbilical cord matrix mesenchymal stem cells,and in vivo by juxtapositional implantation between the tibia and the anterior tibialis muscle in rats.The results showed that the scaffold was not toxic and supported osteogenic differentiation in vitro.HA/aragonite stimulated new bone formation that bridged host bone and intramuscular implants in vivo.We conclude that HA/aragonite is a biodegradable and conductive bone formation biomaterial that stimulates bone regeneration.Since this material is formed near 37°C,it will have great potential for incorporating bioactive molecules to suit personalised application;however,further study of its biodegradation and osteogenic capacity is warranted.The study was approved by the Animal Ethical Committee at Tongji Medical School,Huazhong University of Science and Technology(IACUC No.738)on October 1,2017.展开更多
The natural ligament-bone interface features gradient changes in matrix composition,architecture and cell phenotype,which play critical roles in reliable ligament fixation and smooth loading transfer.Mimicking such or...The natural ligament-bone interface features gradient changes in matrix composition,architecture and cell phenotype,which play critical roles in reliable ligament fixation and smooth loading transfer.Mimicking such organisations in artificial composite tissue-engineering scaffolds is important for realising functional fixation between ligament implants and host bones.Here,the authors aim to provide a comprehensive review on the latest strategies to fabricate biomimetic composite scaffolds for the regeneration of ligament-to-bone interface.The biomimetic composite scaffolds are divided into stratified and gradient scaffolds,which are characterised as layer-specific and continuous changes,respectively,in scaffold materials and/or microstructures.Biofabrication strategies for different types of composite scaffolds are summarised.The effects of material/structural changes on cellular morphology,cell differentiation,in vivo osteointegration and multi-tissue interface regeneration are highlighted.Finally,the potential challenges and future perspectives in engineering biomimetic composite scaffolds for ligament-bone interface regeneration are discussed.展开更多
Plastic surgery is a specialty that is now worldwide recognized as its own academic discipline within the surgical community. The roots however are as old as 600 BC when in the Sushruta Ayurveda the reconstruction of ...Plastic surgery is a specialty that is now worldwide recognized as its own academic discipline within the surgical community. The roots however are as old as 600 BC when in the Sushruta Ayurveda the reconstruction of a nose with a flap from the forehead was described. Plastic surgery is a problem solving discipline that meanwhile is an integral part within modern surgical concepts.展开更多
Bioprinting is a revolutionary technology within the field of tissue engineering that enables the precise fabrication of three-dimensional(3D)tissue constructs.It combines the principles of engineering and biology to ...Bioprinting is a revolutionary technology within the field of tissue engineering that enables the precise fabrication of three-dimensional(3D)tissue constructs.It combines the principles of engineering and biology to create structures that closely mimic the complexity of native human tissues,facilitating advancements in regenerative medicine and personalized healthcare.This review paper systematically explores the challenges and design requirements in the fabrication of 3D biomimetic tissue constructs,emphasizing the need for advanced bioprinting strategies.Achieving biomimicry involves creating 3D anatomically relevant structures,biomimetic microenvironments,and vascularization.The focus is on overcoming existing bottlenecks through advancements in both fabrication techniques and bio-inks.Future directions in bioprinting are outlined,including multi-modal bioprinting systems,in-situ bioprinting,and the integration of machine learning into bioprinting processes.The critical role of bio-inks and printing methodologies in influencing cell viability is highlighted,providing insights into strategies for enhancing cellular functionality throughout the bioprinting process.Furthermore,the paper addresses post-fabrication considerations,particularly in accelerating tissue maturation,as a pivotal component for advancing the clinical applicability of bioprinted tissues.By navigating through the challenges,innovations,and prospects of advanced bioprinting strategies,this review highlights the transformative impact on tissue engineering.Pushing the boundaries of technological capabilities,these strategies hold the promise of groundbreaking advancements in regenerative medicine and personalized healthcare.Ultimately,the integration of these advanced techniques into bioprinting processes will pave the way for the development of more highly biomimetic and functional bioprinted tissues.展开更多
As a follow-up to the successful International Conference on Biomaterials,Bio-Design and Manufacturing(BDMC)held at the National University of Singapore in 2023[1]and at the University of Tokyo in 2024[2],BDMC2025 too...As a follow-up to the successful International Conference on Biomaterials,Bio-Design and Manufacturing(BDMC)held at the National University of Singapore in 2023[1]and at the University of Tokyo in 2024[2],BDMC2025 took place at the University of Oxford in the UK from August 8th to August 10th this year.After the meeting,a participant from the University of Cambridge described his experience of attending BDMC2025 on the social media platform LinkedIn in the following terms:“Many thanks to the organizers for a fantastic event bringing together nearly everyone at the interface of Biofabrication,Materials Science,and Biomedical Engineering”[3].The conference was held on the campus of the University of Oxford and 190 researchers from 55 academic institutions across 10 countries and regions attended(Fig.1).展开更多
This comprehensive review explores the multifaceted landscape of skin bioprinting,revolutionizing dermatological research.The applications of skin bioprinting utilizing techniques like extrusion-,droplet-,laser-and li...This comprehensive review explores the multifaceted landscape of skin bioprinting,revolutionizing dermatological research.The applications of skin bioprinting utilizing techniques like extrusion-,droplet-,laser-and light-based methods,with specialized bioinks for skin biofabrication have been critically reviewed along with the intricate aspects of bioprinting hair follicles,sweat glands,and achieving skin pigmentation.Challenges remain with the need for vascularization,safety concerns,and the integration of automated processes for effective clinical translation.The review further investigates the incorporation of biosensor technologies,emphasizing their role in monitoring and enhancing the wound healing process.While highlighting the remarkable progress in the field,critical limitations and concerns are critically examined to provide a balanced perspective.This synthesis aims to guide scientists,engineers,and healthcare providers,fostering a deeper understanding of the current state,challenges,and future directions in skin bioprinting for transformative applications in tissue engineering and regenerative medicine.展开更多
The three-dimensional (3D)bioprinting technology has progressed tremendously over the past decade.By controlling the size, shape,and architecture of the bioprinted constructs,3D bioprinting allows for the fabrication ...The three-dimensional (3D)bioprinting technology has progressed tremendously over the past decade.By controlling the size, shape,and architecture of the bioprinted constructs,3D bioprinting allows for the fabrication of tissue/organ-like constructs with strong structural-functional similarity with their in vivo counterparts at high fidelity.The bioink,a blend of biomaterials and living cells possessing both high biocompatibility and printability,is a critical component of bioprinting.In particular, gelatin methacryloyl (GelMA)has shown its potential as a viable bioink material due to its suitable biocompatibility and readily tunable physicochemical properties.Current GelMA-based bioinks and relevant bioprinting strategies for GelMA bioprinting are briefly reviewed.展开更多
Owing to the special fo rmation of photopolymerized hydrogels,they can effectively control the formation of hydrogels in space and time.Moreover,the photopolymerized hydrogels have mild formation conditions and biocom...Owing to the special fo rmation of photopolymerized hydrogels,they can effectively control the formation of hydrogels in space and time.Moreover,the photopolymerized hydrogels have mild formation conditions and biocompatibility;therefore,they can be widely used in tissue engineering.With the development and application of manufacturing technology,photopolymerized hydrogels can be widely used in cell encapsulation,scaffold materials,and other tissue engineering fields through more elaborate manufacturing methods.This review covers the types of photoinitiators,manu facturing technologies for photopolymerized hydrogels as well as the materials used,and a summary of the applications of photopolymerized hydrogels in tissue engineering.展开更多
In the past few years,photo-crosslinkable hydrogels have drawn a great attention in tissue engineering applications due to their high biocompatibility and extracellular matrix(ECM)-like structure.They can be easily bi...In the past few years,photo-crosslinkable hydrogels have drawn a great attention in tissue engineering applications due to their high biocompatibility and extracellular matrix(ECM)-like structure.They can be easily biofabricated through exposure of a photosensitive system composed of photo-crosslinkable hydrogels,photo-initiators and other compounds such as cells and therapeutic molecules,to ultraviolet or visible light.With the development ofbiofabrication methods,many researchers studied the biological applications of photo-crosslinkable hydrogels in tissue engineering,such as vascular,wound dressing and bone engineering.This review highlights the biomaterials for photo-crosslinkable hydrogels,biofabrication techniques and their biological applications in tissue engineering.Meanwhile,the challenges and prospects of photo-crosslinkable hydrogels are discussed as well.展开更多
The multidisciplinary research field of bioprinting combines additive manufacturing,biology and material sciences to cre-ate bioconstructs with three-dimensional architectures mimicking natural living tissues.The high...The multidisciplinary research field of bioprinting combines additive manufacturing,biology and material sciences to cre-ate bioconstructs with three-dimensional architectures mimicking natural living tissues.The high interest in the possibility of reproducing biological tissues and organs is further boosted by the ever-increasing need for personalized medicine,thus allowing bioprinting to establish itself in the field of biomedical research,and attracting extensive research efforts from companies,universities,and research institutes alike.In this context,this paper proposes a scientometric analysis and critical review of the current literature and the industrial landscape of bioprinting to provide a clear overview of its fast-changing and complex position.The scientific literature and patenting results for 2000-2020 are reviewed and critically analyzed by retrieving 9314 scientific papers and 309 international patents in order to draw a picture of the scientific and industrial landscape in terms of top research countries,institutions,journals,authors and topics,and identifying the technology hubs worldwide.This review paper thus offers a guide to researchers interested in this field or to those who simply want to under-stand the emerging trends in additive manufacturing and 3D bioprinting.展开更多
Among the different bioprinting techniques,the drop-on-demand(DOD)jetting-based bioprinting approach facilitates contactless deposition of pico/nanoliter droplets ofmaterials and cells for optimal cell–matrix and cel...Among the different bioprinting techniques,the drop-on-demand(DOD)jetting-based bioprinting approach facilitates contactless deposition of pico/nanoliter droplets ofmaterials and cells for optimal cell–matrix and cell–cell interactions.Although bioinks play a critical role in the bioprinting process,there is a poor understanding of the influence of bioink properties on printing performance(such as filament elongation,formation of satellite droplets,and droplet splashing)and cell health(cell viability and proliferation)during the DOD jetting-based bioprinting process.An inert polyvinylpyrrolidone(PVP360,molecular weight=360 kDa)polymerwas used in this study to manipulate the physical properties of the bioinks and investigate the influence of bioink properties on printing performance and cell health.Our experimental results showed that a higher bioink viscoelasticity helps to stabilize droplet filaments before rupturing from the nozzle orifice.The highly stretched droplet filament resulted in the formation of highly aligned“satellite droplets,”which minimized the displacement of the satellite droplets away from the predefined positions.Next,a significant increase in the bioink viscosity facilitated droplet deposition on the wetted substrate surface in the absence of splashing and significantly improved the accuracy of the deposited main droplet.Further analysis showed that cell-laden bioinks with higher viscosity exhibited higher measured average cell viability(%),as the presence of polymer within the printed droplets provides an additional cushioning effect(higher energy dissipation)for the encapsulated cells during droplet impact on the substrate surface,improves the measured average cell viability even at higher droplet impact velocity and retains the proliferation capability of the printed cells.Understanding the influence of bioink properties(e.g.,bioink viscoelasticity and viscosity)on printing performance and cell proliferation is important for the formulation of new bioinks,and we have demonstrated precise DOD deposition of living cells and fabrication of tunable cell spheroids(nL–μL range)using multiple types of cells in a facile manner.展开更多
基金supported by the Program of the National Natural Science Foundation of China(52275291)(52435006)the Program for Innovation Team of Shaanxi Province(2023CX-TD-17)the Fundamental Research Funds for the Central Universities。
文摘Brain,the material foundation of human intelligence,is the most complex tissue in the human body.Brain diseases are among the leading threats to human life,yet our understanding of their pathogenic mechanisms and drug development remains limited,largely due to the lack of accurate brain-like tissue models that replicate its complex structure and functions.Therefore,constructing brain-like models—both in morphology and function—possesses significant scientific value for advancing brain science and pathological pharmacology research,representing the frontiers in the biomanufacturing field.This review outlines the primary requirements and challenges in biomanufacturing brain-like tissue,addressing its complex structures,functions,and environments.Also,the existing biomanufacturing technologies,strategies,and characteristics for brain-like models are depicted,and cutting-edge developments in biomanufacturing central neural repair prosthetics,brain development models,brain disease models,and brain-inspired biocomputing models are systematically reviewed.Finally,the paper concludes with future perspectives on the biomanufacturing of brain-like tissue transitioning from structural manufacturing to intelligent functioning.
基金supported by the National Natural Science Foundation of China(Nos.82302786 and 82172394)the China Postdoctoral Science Foundation(Nos.BX20230245 and 2023M742478)+4 种基金the Sichuan Science and Technology Program(No.2023YFH0068)the Sichuan Province Innovative Talent Funding Project for Postdoctoral Fellows(No.BX202203)the Sichuan University Postdoctoral Interdisciplinary Innovation Fund(No.JCXK2226)1·3·5 Project for Disciplines of Excellence,West China Hospital,Sichuan University(No.ZYGD23033)the Postdoctoral Research Fund of West China Hospital,Sichuan University(No.2023HXBH012).
文摘Three-dimensional(3D)bioprinting provides a rapid and efficient method for fabricating customized bioprinted tissues that replicate the complex architecture of native tissues.However,in 3D bioprinting,the need for dense biomaterial networks to ensure mechanical strength and structural fidelity often restricts the spreading,migration,and proliferation of encapsulated cells,as well as the transport of materials.This review summarizes effective strategies for manufacturing microporous bioprinted tissues via 3D bioprinting.The term“microporous”refers to interconnected,micrometer-sized pore-like structures within the internal materials of bioprinted tissues,including the microstructure of a single extruded fiber in extrusion printing.This differs from the macroscopic pore structure formed between fibers composed of print tracks or computer-aided design presets.These micropores play a crucial role in advancing biomanufacturing and 3D bioprinting by providing space for cell adhesion and proliferation while facilitating the timely transport of nutrients and metabolic waste essential for cell growth.Additionally,microporous bioprinted tissues offer the mechanical support needed for cell seeding and serve as sites for extracellular matrix deposition.As microporous 3D bioprinting continues to advance,it has the potential to address unresolved challenges in fields such as organ transplantation,tissue regeneration,and tissue replacement.
文摘Animal models have been extensively used in cancer pathology studies and drug discovery.These models,however,fail to reflect the complex human tumor microenvironment and do not allow for high-throughput drug screening in more human-like physiological conditions.Three-dimensional(3D)cancer models present an alternative to automated high-throughput cancer drug discovery and oncology.In this review,we highlight recent technology innovations in building 3D tumor models that simulate the complex human tumor microenvironment and responses of patients to treatment.We discussed various biofabrication technologies,including 3D bioprinting techniques developed for characterizing tumor progression,metastasis,and response to treatment.
文摘Technological and economic opportunities,alongside the apparent ecological benefits,point to biodesign as a new industrial paradigm for the fabrication of products in the twenty-first century.The presented work studies plant roots as a biodesign material in the fabrication of self-supported 3D structures,where the biologically and digitally designed materials provide each other with structural stability.Taking a material-driven design approach,we present our systematic tinkering activities with plant roots to better understand and anticipate their responsive behaviour.These helped us to identify the key design parameters and advance the unique potential of plant roots to bind discrete porous structures.We illustrate this binding potential of plant roots with a hybrid 3D object,for which plant roots connect 600 computationally designed,optimized,and fabricated bioplastic beads into a low stool.
基金supported by National Key Research and Development Program of China(Grant Nos.2023YFC2411300,2023YFB4605800)National Natural Science Foundation of China(Grant No.32471474)+2 种基金Sichuan Science and Technology Program(Grant Nos.2024YFHZ0125,2022NSFSC1405)China Postdoctoral Science Foundation(Grant No.2022M722268)Research and Develop Program,West China Hospital of Stomatology Sichuan University(Grant No.RD-03-202406).
文摘Biofabrication,also known as bioprinting,has been widely used in the field of biomedicine.The three most important factors in biofabrication are 3D bioprinter,biomaterials to be printed(bioinks),and the printing object(application).This review provides a detailed introduction to the latest research progress in these aspects.In particularly,the bioinks for bioprinting require strict biocompatible requirements.Four typical materials,i.e.metal/alloys,ceramics,polymers,and their composites,were introduced in detail,and their printing process and application scenarios were summarized,respectively.There are many applications of biofabrication in clinical practice.The application of biofabrication in skeletal system,skin and soft tissue,cardiovascular system,digestive system,respiratory system,urinary system,nervous system,plastic surgery and medical aesthetics were briefly introduced.The applications of biofabrication has a wide range of clinical need.Biofabrication is an innovative technology that is expected to further promote the clinical precision treatments.
文摘Objective:To formulate a simple rapid procedure for bioreduction of silver nanoparticles using aqueous leaves extract of Moringa oleifera(M.oleifera).Methods:10 mL of leaf extract was mixed to 90 mL of 1 mM aqueous of AgNO_3 and was heated at 60-80 ℃ for 20 min.A change from brown to reddish color was observed.Characterization using UV-Vis spectrophotometry, Transmission Electron Microscopy(TEM) was performed.Results:TEM showed the formation of silver nanoparticles with an average size of 57 nm.Conclusions:M.oleifera demonstrates strong potential for synthesis of silver nanoparticles by rapid reduction of silver ions(Ag^+ to Ag^0). Biological methods are good competents for the chemical procedures,which are eco-friendly and convenient.
基金supported by the National Natural Science Foundation of China(NSFC)Program(No.32201183).
文摘While traditional bulk hydrogels have been widely used in 3D bioprinting for tissue engineering,engineered cell-loaded scaffolds still fall short of expectations because their nanoscale molecular networks impede cell function.Microgels,as micronsized hydrogel materials,offer significant advantages in enhancing mass transport and tissue permeability,while concurrently promoting cellular proliferation,migration,and differentiation.Incorporating microgels as bioinks into 3D bioprinting enables customization of shape,mechanical properties,and functionality,significantly expanding the applications of hydrogel materials and addressing diverse bioprinting needs.Hierarchically porous scaffolds formed by microgel assembly leverage dual-scale porosity:nanoporosity inherent in the material and microporosity originating from the assembly.This unique structure promotes tissue regeneration and facilitates microtissue assembly.This review provides an overview of microgel fabrication techniques,describing their role as carriers for cells and biomolecules,as well as their applications in 3D biofabrication.Notably,we throughout present the application of microgels in 3D biofabrication.Finally,we provide an outlook on the potential applications of microgels in biomedical engineering and their integration with emerging printing technologies.
基金funding from National Key Research and Development Program of China(No.2018YFA0703000)The National Natural Science Foundation of China No.52275294 and supports from Zhejiang University Global Partnership Fundthe financial support from Chinese Scholar Councils(CSC)Scholarship fund.We would also like to thank Dr.Zhaoying Li and Dr.Elisabeth Lauren Gill for their essential contributions.
文摘In the human body,almost all cells interact with extracellular matrices(ECMs),which have tissue and organ-specific compositions and architectures.These ECMs not only function as cellular scaffolds,providing structural support,but also play a crucial role in dynamically regulating various cellular functions.This comprehensive review delves into the examination of biofabrication strategies used to develop bioactive materials that accurately mimic one or more biophysical and biochemical properties of ECMs.We discuss the potential integration of these ECM-mimics into a range of physiological and pathological in vitro models,enhancing our understanding of cellular behavior and tissue organization.Lastly,we propose future research directions for ECM-mimics in the context of tissue engineering and organ-on-a-chip applications,offering potential advancements in therapeutic approaches and improved patient outcomes.
基金The authors acknowledge the funding support from the EPSRC(Funding Reference Number EP/L015995/1&EP/W004860/1)the Royal Society(IEC\NSFC\201166)+1 种基金the National Natural Science Foundation of China(No.82111530157)the Priority Academic Program Development(PAPD)of Jiangsu Higher Education Institutions。
文摘There is a high demand for bespoke grafts to replace damaged or malformed bone and cartilage tissue.Three-dimensional(3D)printing offers a method of fabricating complex anatomical features of clinically relevant sizes.However,the construction of a scaffold to replicate the complex hierarchical structure of natural tissues remains challenging.This paper reports a novel biofabrication method that is capable of creating intricately designed structures of anatomically relevant dimensions.The beneficial properties of the electrospun fibre meshes can finally be realised in 3D rather than the current promising breakthroughs in two-dimensional(2D).The 3D model was created from commercially available computer-aided design software packages in order to slice the model down into many layers of slices,which were arrayed.These 2D slices with each layer of a defined pattern were laser cut,and then successfully assembled with varying thicknesses of 100μm or 200μm.It is demonstrated in this study that this new biofabrication technique can be used to reproduce very complex computer-aided design models into hierarchical constructs with micro and nano resolutions,where the clinically relevant sizes ranging from a simple cube of 20 mm dimension,to a more complex,50 mm-tall human ears were created.In-vitro cell-contact studies were also carried out to investigate the biocompatibility of this hierarchal structure.The cell viability on a micromachined electrospun polylactic-co-glycolic acid fibre mesh slice,where a range of hole diameters from 200μm to 500μm were laser cut in an array where cell confluence values of at least 85%were found at three weeks.Cells were also seeded onto a simpler stacked construct,albeit made with micromachined poly fibre mesh,where cells can be found to migrate through the stack better with collagen as bioadhesives.This new method for biofabricating hierarchical constructs can be further developed for tissue repair applications such as maxillofacial bone injury or nose/ear cartilage replacement in the future.
基金This study was supported by the Wuhan International Collaboration Project of China(No.2017030209020252)Wuhan Science and Technology Project of China(No.2018010401011281).
文摘A self-hardening three-dimensional(3D)-porous composite bone graft consisting of 65 wt%hydroxyapatite(HA)and 35 wt%aragonite was fabricated using a 3D-Bioplotter®.New tetracalcium phosphate and dicalcium phosphate anhydrous/aragonite/gelatine paste formulae were developed to overcome the phase separation of the liquid and solid components.The mechanical properties,porosity,height and width stability of the end products were optimised through a systematic analysis of the fabrication processing parameters including printing pressure,printing speed and distance between strands.The resulting 3D-printed bone graft was confirmed to be a mixture of HA and aragonite by X-ray diffraction,Fourier transform infrared spectroscopy and energy dispersive X-ray spectroscopy.The compression strength of HA/aragonite was between 0.56 and 2.49 MPa.Cytotoxicity was assessed using the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide(MTT)assay in vitro.The osteogenicity of HA/aragonite was evaluated in vitro by alkaline phosphatase assay using human umbilical cord matrix mesenchymal stem cells,and in vivo by juxtapositional implantation between the tibia and the anterior tibialis muscle in rats.The results showed that the scaffold was not toxic and supported osteogenic differentiation in vitro.HA/aragonite stimulated new bone formation that bridged host bone and intramuscular implants in vivo.We conclude that HA/aragonite is a biodegradable and conductive bone formation biomaterial that stimulates bone regeneration.Since this material is formed near 37°C,it will have great potential for incorporating bioactive molecules to suit personalised application;however,further study of its biodegradation and osteogenic capacity is warranted.The study was approved by the Animal Ethical Committee at Tongji Medical School,Huazhong University of Science and Technology(IACUC No.738)on October 1,2017.
基金The Youth Innovation Team of Shaanxi Universitiesthe National Key Research and Development Program of China,Grant/Award Number:2018YFA0703000+4 种基金the Fundamental Research Funds for the Central UniversitiesGuangdong Basic and Applied Basic Research Foundation,Grant/Award Number:2020B1515130002the Key Research Project of Shaanxi Province,Grant/Award Numbers:2020GXLH-Y-021,2021GXLH-Z-028the Basic Research Program of Natural Science in Shaanxi Province,Grant/Award Number:2021JQ-906the National Natural Science Foundation of China,Grant/Award Number:81601937。
文摘The natural ligament-bone interface features gradient changes in matrix composition,architecture and cell phenotype,which play critical roles in reliable ligament fixation and smooth loading transfer.Mimicking such organisations in artificial composite tissue-engineering scaffolds is important for realising functional fixation between ligament implants and host bones.Here,the authors aim to provide a comprehensive review on the latest strategies to fabricate biomimetic composite scaffolds for the regeneration of ligament-to-bone interface.The biomimetic composite scaffolds are divided into stratified and gradient scaffolds,which are characterised as layer-specific and continuous changes,respectively,in scaffold materials and/or microstructures.Biofabrication strategies for different types of composite scaffolds are summarised.The effects of material/structural changes on cellular morphology,cell differentiation,in vivo osteointegration and multi-tissue interface regeneration are highlighted.Finally,the potential challenges and future perspectives in engineering biomimetic composite scaffolds for ligament-bone interface regeneration are discussed.
文摘Plastic surgery is a specialty that is now worldwide recognized as its own academic discipline within the surgical community. The roots however are as old as 600 BC when in the Sushruta Ayurveda the reconstruction of a nose with a flap from the forehead was described. Plastic surgery is a problem solving discipline that meanwhile is an integral part within modern surgical concepts.
基金support from NTU Presidential Postdoctoral Fellowshipthe support from the National Research Foundation,Singapore,under its NRF Investigatorship(NRFNRFI07-2021-007,Funding Awardee:Wai Yee Yeong)。
文摘Bioprinting is a revolutionary technology within the field of tissue engineering that enables the precise fabrication of three-dimensional(3D)tissue constructs.It combines the principles of engineering and biology to create structures that closely mimic the complexity of native human tissues,facilitating advancements in regenerative medicine and personalized healthcare.This review paper systematically explores the challenges and design requirements in the fabrication of 3D biomimetic tissue constructs,emphasizing the need for advanced bioprinting strategies.Achieving biomimicry involves creating 3D anatomically relevant structures,biomimetic microenvironments,and vascularization.The focus is on overcoming existing bottlenecks through advancements in both fabrication techniques and bio-inks.Future directions in bioprinting are outlined,including multi-modal bioprinting systems,in-situ bioprinting,and the integration of machine learning into bioprinting processes.The critical role of bio-inks and printing methodologies in influencing cell viability is highlighted,providing insights into strategies for enhancing cellular functionality throughout the bioprinting process.Furthermore,the paper addresses post-fabrication considerations,particularly in accelerating tissue maturation,as a pivotal component for advancing the clinical applicability of bioprinted tissues.By navigating through the challenges,innovations,and prospects of advanced bioprinting strategies,this review highlights the transformative impact on tissue engineering.Pushing the boundaries of technological capabilities,these strategies hold the promise of groundbreaking advancements in regenerative medicine and personalized healthcare.Ultimately,the integration of these advanced techniques into bioprinting processes will pave the way for the development of more highly biomimetic and functional bioprinted tissues.
文摘As a follow-up to the successful International Conference on Biomaterials,Bio-Design and Manufacturing(BDMC)held at the National University of Singapore in 2023[1]and at the University of Tokyo in 2024[2],BDMC2025 took place at the University of Oxford in the UK from August 8th to August 10th this year.After the meeting,a participant from the University of Cambridge described his experience of attending BDMC2025 on the social media platform LinkedIn in the following terms:“Many thanks to the organizers for a fantastic event bringing together nearly everyone at the interface of Biofabrication,Materials Science,and Biomedical Engineering”[3].The conference was held on the campus of the University of Oxford and 190 researchers from 55 academic institutions across 10 countries and regions attended(Fig.1).
基金supported by National Institutes of Health Award(Nos.R01DE028614(I T O)and R21AR082668(I T O)),and 2236 CoCirculation2 of TUBITAK award(No.121C359(I T O))supported by The Assistant Secretary of Defense for Health Affairs endorsed by the Department of Defense,in the amount of($1986275)through the Peer Reviewed Medical Research Program under Award Number(No.HT9425-23-1-0487)。
文摘This comprehensive review explores the multifaceted landscape of skin bioprinting,revolutionizing dermatological research.The applications of skin bioprinting utilizing techniques like extrusion-,droplet-,laser-and light-based methods,with specialized bioinks for skin biofabrication have been critically reviewed along with the intricate aspects of bioprinting hair follicles,sweat glands,and achieving skin pigmentation.Challenges remain with the need for vascularization,safety concerns,and the integration of automated processes for effective clinical translation.The review further investigates the incorporation of biosensor technologies,emphasizing their role in monitoring and enhancing the wound healing process.While highlighting the remarkable progress in the field,critical limitations and concerns are critically examined to provide a balanced perspective.This synthesis aims to guide scientists,engineers,and healthcare providers,fostering a deeper understanding of the current state,challenges,and future directions in skin bioprinting for transformative applications in tissue engineering and regenerative medicine.
基金the National Institutes of Health (K99CA201603,R21EB025270, R21EB026175)Doctoral New Investigator Grant from American Chemical Society Petroleum Research Fund (56840-DNI7).G.L. Y.acknowledges Natural and Science Foundation of Hubei Province (2014CFB778).
文摘The three-dimensional (3D)bioprinting technology has progressed tremendously over the past decade.By controlling the size, shape,and architecture of the bioprinted constructs,3D bioprinting allows for the fabrication of tissue/organ-like constructs with strong structural-functional similarity with their in vivo counterparts at high fidelity.The bioink,a blend of biomaterials and living cells possessing both high biocompatibility and printability,is a critical component of bioprinting.In particular, gelatin methacryloyl (GelMA)has shown its potential as a viable bioink material due to its suitable biocompatibility and readily tunable physicochemical properties.Current GelMA-based bioinks and relevant bioprinting strategies for GelMA bioprinting are briefly reviewed.
基金financially supported by the National Natural Science Fund for Distinguished Young Scholars(No.31525009)the National Natural Science Foundation of China(Nos.31930067,31771096)+1 种基金the National Key Research and Development Program of China(No.2017YFC1103502)1·3·5 Project for Disciplines of Excellence,West China Hospital,Sichuan University(No.ZYGD18002)。
文摘Owing to the special fo rmation of photopolymerized hydrogels,they can effectively control the formation of hydrogels in space and time.Moreover,the photopolymerized hydrogels have mild formation conditions and biocompatibility;therefore,they can be widely used in tissue engineering.With the development and application of manufacturing technology,photopolymerized hydrogels can be widely used in cell encapsulation,scaffold materials,and other tissue engineering fields through more elaborate manufacturing methods.This review covers the types of photoinitiators,manu facturing technologies for photopolymerized hydrogels as well as the materials used,and a summary of the applications of photopolymerized hydrogels in tissue engineering.
基金This work was supported by the National Natural Science Foundation of China(Nos.81601613,81771122,81970985,81970984,81901060)Key Research Program of Sichuan Science and Technology Department(Nos.2018SZ0037,2019YFS0142,19YYJC2625).
文摘In the past few years,photo-crosslinkable hydrogels have drawn a great attention in tissue engineering applications due to their high biocompatibility and extracellular matrix(ECM)-like structure.They can be easily biofabricated through exposure of a photosensitive system composed of photo-crosslinkable hydrogels,photo-initiators and other compounds such as cells and therapeutic molecules,to ultraviolet or visible light.With the development ofbiofabrication methods,many researchers studied the biological applications of photo-crosslinkable hydrogels in tissue engineering,such as vascular,wound dressing and bone engineering.This review highlights the biomaterials for photo-crosslinkable hydrogels,biofabrication techniques and their biological applications in tissue engineering.Meanwhile,the challenges and prospects of photo-crosslinkable hydrogels are discussed as well.
基金the collaboration agreement between the Italian Space Agency and Politecnico di Milano,“Attivitàdi Ricerca e Innovazione”Agreement n.2018-5-HH.0.
文摘The multidisciplinary research field of bioprinting combines additive manufacturing,biology and material sciences to cre-ate bioconstructs with three-dimensional architectures mimicking natural living tissues.The high interest in the possibility of reproducing biological tissues and organs is further boosted by the ever-increasing need for personalized medicine,thus allowing bioprinting to establish itself in the field of biomedical research,and attracting extensive research efforts from companies,universities,and research institutes alike.In this context,this paper proposes a scientometric analysis and critical review of the current literature and the industrial landscape of bioprinting to provide a clear overview of its fast-changing and complex position.The scientific literature and patenting results for 2000-2020 are reviewed and critically analyzed by retrieving 9314 scientific papers and 309 international patents in order to draw a picture of the scientific and industrial landscape in terms of top research countries,institutions,journals,authors and topics,and identifying the technology hubs worldwide.This review paper thus offers a guide to researchers interested in this field or to those who simply want to under-stand the emerging trends in additive manufacturing and 3D bioprinting.
文摘Among the different bioprinting techniques,the drop-on-demand(DOD)jetting-based bioprinting approach facilitates contactless deposition of pico/nanoliter droplets ofmaterials and cells for optimal cell–matrix and cell–cell interactions.Although bioinks play a critical role in the bioprinting process,there is a poor understanding of the influence of bioink properties on printing performance(such as filament elongation,formation of satellite droplets,and droplet splashing)and cell health(cell viability and proliferation)during the DOD jetting-based bioprinting process.An inert polyvinylpyrrolidone(PVP360,molecular weight=360 kDa)polymerwas used in this study to manipulate the physical properties of the bioinks and investigate the influence of bioink properties on printing performance and cell health.Our experimental results showed that a higher bioink viscoelasticity helps to stabilize droplet filaments before rupturing from the nozzle orifice.The highly stretched droplet filament resulted in the formation of highly aligned“satellite droplets,”which minimized the displacement of the satellite droplets away from the predefined positions.Next,a significant increase in the bioink viscosity facilitated droplet deposition on the wetted substrate surface in the absence of splashing and significantly improved the accuracy of the deposited main droplet.Further analysis showed that cell-laden bioinks with higher viscosity exhibited higher measured average cell viability(%),as the presence of polymer within the printed droplets provides an additional cushioning effect(higher energy dissipation)for the encapsulated cells during droplet impact on the substrate surface,improves the measured average cell viability even at higher droplet impact velocity and retains the proliferation capability of the printed cells.Understanding the influence of bioink properties(e.g.,bioink viscoelasticity and viscosity)on printing performance and cell proliferation is important for the formulation of new bioinks,and we have demonstrated precise DOD deposition of living cells and fabrication of tunable cell spheroids(nL–μL range)using multiple types of cells in a facile manner.
