Novel insights in basic and applied stem cell therapy

The achievement of novel findings in stem cell research were the subject of the meeting organized by Stem Cell Research Italy (SCR Italy) and by the International Society for Cellular Therapy-Europe (ISCT). Stem cell therapy represents great promise for the future of molecular and regenerative medicine. The use of several types of stem cells is a real opportunity to provide a valid approach to curing several untreatable human diseases. Before it is suitable for clinical applications, stem cell biology needs to be investigated further and in greater detail. Basic stem cell research could provide exact knowledge regarding stem cell action mechanisms, and pre-clinical research on stem cells on an in vivo model of disease provides scientific evidence for future human applications. Applied stem cell research is a promising new approach to handling several diseases. Along with tissue engineering, it offers a new and promising discipline that can help to manage human pathologies through stem cell therapy. All of these themes were discussed in this meeting, covering stem cell subtypes with their newest basic and applied research.     

Stem cell differentiation and expansion for clinical applications of tissue engineering

This invited review discusses the latest advances stem cell biology, tissue engineering and the transition from bench to bedside. An overview is presented as to which the best cell source might be for cell therapy and tissue engineering applications, best biomaterials currently available and the challenges the field faces to translate basic research into therapies for a large number of human diseases.     

Nano-regenerative medicine towards clinical outcome of stem cell and tissue engineering in humans

Nanotechnology is a fast growing area of research that aims to create nanomaterials or nanostructures development in stem cell and tissue-based therapies. Concepts and discoveries from the fields of bio nano research provide exciting opportunities of using stem cells for regeneration of tissues and organs. The application of nanotechnology to stem-cell biology would be able to address the challenges of disease therapeutics. This review covers the potential of nanotechnology approaches towards regenerative medicine. Furthermore, it focuses on current aspects of stem- and tissue-cell engineering. The magnetic nanoparticles-based applications in stem-cell research open new frontiers in cell and tissue engineering.     

Canine embryonic stem cells: State of the art

Embryonic stem cells (ESCs) are permanent cell lines that can be maintained in a pluripotent, undifferentiated state. Appropriate environmental stimuli can cause them to differentiate into cell types of all three germ layers both in vitro and in vivo. Embryonic stem cells bear many opportunities for clinical applications in tissue engineering and regenerative medicine. Whereas most of our knowledge on the biology and technology of ESCs is derived from studies with mouse cells, large animal models mimicking important aspects of human anatomy, physiology, and pathology more closely than mouse models are urgently needed for studies evaluating the safety and efficacy of cell therapies. The dog is an excellent model for studying human diseases, and the availability of canine ESCs would open new possibilities for this model in biomedical research. In addition, canine ESCs could be useful for the development of cell-based approaches for the treatment of dogs. Here, we discuss the features of recently reported canine embryo-derived cells and their potential applications in basic and translational biomedical research.     

Adipose-derived stem cells: isolation, expansion and differentiation

The emerging field of regenerative medicine will require a reliable source of stem cells in addition to biomaterial scaffolds and cytokine growth factors. Adipose tissue has proven to serve as an abundant, accessible and rich source of adult stem cells with multipotent properties suitable for tissue engineering and regenerative medical applications. There has been increased interest in adipose-derived stem cells (ASCs) for tissue engineering applications. Here, methods for the isolation, expansion and differentiation of ASCs are presented and described in detail. While this article has focused on the isolation of ASCs from human adipose tissue, the procedure can be applied to adipose tissues from other species with minimal modifications.     

组织工程的突破与挑战——组织工程国家工程中心科研进展

组织工程技术已被普遍认为是解决组织、器官缺损修复与功能重建的有效手段,它的飞速发展依赖于细胞学、材料学、工程学、临床医学等多学科的交叉渗透.作为组织工程的三大核心,种子细胞、生物材料、组织构建各方面的突破,为组织工程技术的发展奠定了基础.组织工程国家工程中心近年来围绕上述核心开展了系列研究,通过研究胚胎干细胞、成体干细胞、同种异体干细胞、以及发育同源细胞替代的探索,为解决种子细胞来源问题提供了多种选择;生物支架材料的开发,为细胞增殖分化、组织再生提供理想的支持与空间,而生物反应器的开发与应用,进一步提高了组织构建技术,为促进组织的体外形成、重塑和功能成熟创造了条件.在此基础上,开展了大动物体内组织构建和缺损修复的研究,形成了以应用为目标的研究特色,并成功将部分技术应用于临床治疗.本文将对组织工程国家工程中心已有进展做简单介绍并对面临的挑战进行分析.     

Effective surface-based cryopreservation of human embryonic stem cells by vitrification

Human embryonic stem cells (hESCs) are candidates for many applications in the areas of regenerative medicine, tissue engineering, basic scientific research as well as pharmacology and toxicology. However, use of hESCs is limited by their sensitivity to freezing and thawing procedures. Hence, this emerging science needs new, reliable preservation methods for the long-term storage of large quantities of functional hESCs remaining pluripotent after post-thawing and culturing.Here, we present a highly efficient, surface based vitrification method for the cryopreservation of large numbers of adherent hESC colonies, using modified cell culture substrates. This technique results in much better post-thaw survival rate compared to cryopreservation in suspension and allows a quick and precise handling and storage of the cells, indicating low differentiation rates.     

Immune response to stem cells and strategies to induce tolerance

Although recent progress in cardiovascular tissue engineering has generated great expectations for the exploitation of stem cells to restore cardiac form and function, the prospects of a common mass-produced cell resource for clinically viable engineered tissues and organs remain problematic. The refinement of stem cell culture protocols to increase induction of the cardiomyocyte phenotype and the assembly of transplantable vascularized tissue are areas of intense current research, but the problem of immune rejection of heterologous cell type poses perhaps the most significant hurdle to overcome. This article focuses on the potential advantages and problems encountered with various stem cell sources for reconstruction of the damaged or failing myocardium or heart valves and also discusses the need for integrating advances in developmental and stem cell biology, immunology and tissue engineering to achieve the full potential of cardiac tissue engineering. The ultimate goal is to produce 'off-the-shelf' cells and tissues capable of inducing specific immune tolerance.     

Cardiospheres and tissue engineering for myocardial regeneration: potential for clinical application

Tissue engineering is an increasingly expanding area of research in the cardiovascular field that involves engineering, chemistry, biology and medicine. Cardiac tissue engineering (CTE) aims to regenerate myocardial damage by combining cells, matrix, biological active molecules and physiological stimuli. The rationale behind CTE applications is that in order to regenerate the ventricular wall after a myocardial infarction it is necessary to combine procedures that regenerate both cardiomyocytes and the extracellular matrix. The application of (stem) cells together with a matrix could represent an environment protected from the inflammatory and pro-apoptotic signals, a stemness/survival reservoir slowly releasing cells and factors promoting tissue regeneration and angiogenesis. This review will focus on the applications and advantages that CTE application could offer compared to conventional cell therapy.     

Perinatal stem cells: A promising cell resource for tissue engineering of craniofacial bone

In facing the mounting clinical challenge and suboptimal techniques of craniofacial bone defects resulting from various conditions, such as congenital malformations, osteomyelitis, trauma and tumor resection, the ongoing research of regenerative medicine using stem cells and concurrent advancement in biotechnology have shifted the focus from surgical reconstruction to a novel stem cell-based tissue engineering strategy for customized and functional craniofacial bone regeneration. Given the unique ontogenetical and cell biological properties of perinatal stem cells, emerging evidence has suggested these extraembryonic tissue-derived stem cells to be a promising cell source for extensive use in regenerative medicine and tissue engineering. In this review, we summarize the current achievements and obstacles in stem cell-based craniofacial bone regeneration and subsequently we address the characteristics of various types of perinatal stem cells and their novel application in tissue engineering of craniofacial bone. We propose the promising feasibility and scope of perinatal stem cell-based craniofacial bone tissue engineering for future clinical application.     

Adult mesenchymal stem cells and cell-based tissue engineering

The identification of multipotential mesenchymal stem cells (MSCs) derived from adult human tissues, including bone marrow stroma and a number of connective tissues, has provided exciting prospects for cell-based tissue engineering and regeneration. This review focuses on the biology of MSCs, including their differentiation potentials in vitro and in vivo, and the application of MSCs in tissue engineering. Our current understanding of MSCs lags behind that of other stem cell types, such as hematopoietic stem cells. Future research should aim to define the cellular and molecular fingerprints of MSCs and elucidate their endogenous role(s) in normal and abnormal tissue functions.     

Adult mesenchymal stem cells and cell-based tissue engineering

The identification of multipotential mesenchymal stem cells (MSCs) derived from adult human tissues, including bone marrow stroma and a number of connective tissues, has provided exciting prospects for cell-based tissue engineering and regeneration. This review focuses on the biology of MSCs, including their differentiation potentials in vitro and in vivo, and the application of MSCs in tissue engineering. Our current understanding of MSCs lags behind that of other stem cell types, such as hematopoietic stem cells. Future research should aim to define the cellular and molecular fingerprints of MSCs and elucidate their endogenous role(s) in normal and abnormal tissue functions.     

Engineering tissue from human embryonic stem cells

Recent advances in human embryonic stem cell (hESC) biology now offer an alternative cell source for tissue engineers, as these cells are capable of proliferating indefinitely and differentiating to many clinically relevant cell types. Novel culture methods capable of exerting spatial and temporal control over the stem cell microenvironment allow for more efficient expansion of hESCs, and significant advances have been made toward improving our understanding of the biophysical and biochemical cues that direct stem cell fate choices. Effective production of lineage specific progenitors or terminally differentiated cells enables researchers to incorporate hESC derivatives into engineered tissue constructs. Here, we describe current efforts using hESCs as a cell source for tissue engineering applications, highlighting potential advantages of hESCs over current practices as well as challenges which must be overcome.     

Unraveling the molecular components and genetic blueprints of stem cells

Remarkable progress in stem cell biology research over the past few years has provoked a promise for the future of tissue regeneration and gene therapies; so much so, that the use of stem cells in clinical therapy seemed to be just around the corner. However, we now realize there is still a huge task before us to improve our understanding of the nature of stem cells before utilizing them to benefit human health. Stem cell behavior is determined by specific gene products; thus, unraveling the molecular components and genetic blueprints of stem cells will provide important insight into understanding stem cell properties. Here we summarize the research of various groups using microarray technology and other approaches to determine the gene expression profiles in stem cells, particularly in hematopoietic stem cells (HSCs). These works have, to a certain degree, helped to narrow down the candidate genes predominantly expressed in HSCs, revealed a list of stemness genes, and indirectly demonstrated the wide-open chromatin state of stem cells and, with it, the molecular basis of the multipotentiality of stem cells.     

综述: 诱导重编程过程中的表观遗传重塑

多能干细胞(pluripotent stem cell,PSC)是一类具有自我更新能力和多向分化潜能的细胞,具有广泛的临床应用前景．诱导性多功能干细胞(induced pluripotent stem cell,iPS cell)的获得,解决了传统方式中的细胞来源和伦理学等问题,从理论研究和应用上实现了体细胞重编程的重大突破,也为疾病发生机制研究、药物筛选、个性化药物选择、细胞治疗和再生医学等研究创造了难得的机会,从而开启了多能干细胞应用的新纪元．iPS过程中有很多问题尚未得到解决,尤其是诱导重编程的分子机制方面,这也是近年来干细胞领域研究的热点．其中如何实现表观遗传的重编程被认为是亟待解决的核心问题之一．本文结合我们的研究,主要介绍诱导重编程领域表观遗传修饰重塑机制的研究进展,并展望未来研究中大规模信息整合分析的重要性．     

下一代测序技术在干细胞转录调控研究中的应用

基因转录调控及其机制分析是后基因组时代生物学研究的重点之一。随着高通量测序技术的发展,人们可以从不同层面研究基因的转录调控行为,从转录组、转录因子结合,到染色质局部结构和整体空间构象,可系统分析转录调控的分子机制。干细胞分化过程的转录调控分析对研究再生医学和理解细胞癌变机制等具有重要意义。本文综述了下一代测序技术在干细胞转录调控研究中的应用,包括：(1)基于基因芯片或RNA测序的转录组分析;(2)基于染色体免疫共沉淀(chromatin immunoprecipitation, ChIP)测序的表观基因组和转录因子结合信息的分析;(3)基于DNase 酶切测序(DNase-Seq)的染色质开放性分析;(4)基于高通量染色质构象捕获(high-throughput chromosome conformation capture, Hi-C)技术的染色体远程相互作用分析。从基因表达谱、转录因子结合和基因组三维结构等层面展开介绍,重点关注了一些多能性转录因子(Oct4、Sox2和Nanog等)在维持干细胞干性和分化中的调控作用,以期为干细胞转录调控的研究提供借鉴和参考。     

慢性肾功能衰竭的治疗现状及研究前景

CRF是威胁人类健康及生命的常见病之一,近年来平均每年以约8%的速度在增长。依靠慢性肾功能衰竭肾脏母体及机体的再生潜能在脱细胞基质支架上修复重建肾脏结构与功能,这将是慢性肾功能衰竭治疗的一种全新的途径。而去细胞基质在组织工程、干细胞及再生医学的大量应用为解决组织器官的修复和重建等难题带来了希望。本文就目前CRF的治疗现状及、肾脏组织工程研究前景进行简要综述。     

干细胞与组织工程

随着生物材料、生物反应器设计及对机体发育和创伤修复机制的深入理解,在体外构建用于修复替代人体丧失功能的组织器官这一人类理想,已发展成一门独立且蓬勃发展的学科——组织工程学（Tissue Engineering）。组织工程学是一个多学科交叉的新兴领域,至少涉及生命科学、医学及工程学等三个学科。种子细胞、支架材料和诱导信号是组织工程学的三个基本要素。目前种子细胞是制约组织工程发展的一个主要瓶颈。干细胞生物学的发展使人们看到了打破这个瓶颈的可能。干细胞体外扩增及定向分化的技术发展,及对其增殖和诱导分化机制的深入理解,使工程化组织可以获得理想的基本功能单位,使其应用于临床成为可能。