细胞药物的临床应用——细胞药物连载之五

近年来,细胞药物在基础研究领域的成果促进了临床应用。现在细胞药物治疗的疾病种类很多,包括神经系统疾病、自身免疫系统疾病、心血管系统疾病、血液系统疾病、消化系统疾病、下肢缺血、整形美容、抗衰老及抗肿瘤等,涉及的细胞主要有各种干细胞、软骨细胞、肝细胞、DC及CIK细胞等。国内外越来越多的机构和组织开展了细胞治疗的临床研究及应用。     

讲座细胞药物的制备工艺——细胞药物连载之二

细胞药物制备的质量直接关系到细胞治疗的效果。由于细胞治疗所用细胞是具有生物学效应的,细胞药物的制备技术和应用方案具有多样性、复杂性和特殊性,不像一般生物药物那样有统一的制作标准。细胞药物的制备过程主要包括供者筛查、供者检测、采集、加工、分离纯化、储存等,以造血干细胞、间充质干细胞、肝细胞及树突状细胞为例对其进行简要介绍。     

细胞药物的研发现状——细胞药物连载之三

近年来,细胞药物的研究受到了国内外重视。特别是干细胞药物,已成为世界各国竞相研究的热点领域,但各国的干细胞药物绝大多数仍处于研究阶段,全球真正上市的干细胞药物很少。目前正在研发的干细胞药物主要集中在治疗慢性疾病（关节炎、糖尿病和癌症等）和心脏相关疾病（心肌梗死、心脏衰竭等）。一些传统体细胞药物（软骨细胞、心肌细胞、胰岛细胞等）和免疫细胞药物已在临床应用。     

细胞药物的制备工艺——细胞药物 连载之二

细胞药物制备的质量直接关系到细胞治疗的效果。由于细胞治疗所用细胞是具有生物学效应的,细胞药物的制备技术和应用方案具有多样性、复杂性和特殊性,不像一般生物药物那样有统一的制作标准。细胞药物的制备过程主要包括供者筛查、供者检测、采集、加工、分离纯化、储存等,以造血干细胞、间充质干细胞、肝细胞及树突状细胞为例对其进行简要介绍。     

干细胞生物药物研究进展

胚胎干细胞和成年干细胞经培养能产生更多干细胞也可定向分化成神经细胞、血细胞、肝细胞等特定类型的细胞。其中具有潜能的细胞可用来研究治疗帕金森病、糖尿病和脊髓损伤等疾病的生物药物。     

口腔鳞癌细胞系NTCR中侧群细胞的相关研究

目的:口腔鳞癌是口腔颌面部常见的恶性肿瘤之一,本研究以侧群细胞为肿瘤干细胞突破口,通过检测、分选口腔鳞癌细胞系NTCR中侧群细胞(side population,SP)细胞亚群,深入研究不同细胞亚群的体内、外相关生物学特性,寻找口腔鳞癌中肿瘤干细胞存在的证据。方法:选取口腔鳞癌细胞系NTCR作为研究对象,Hoechst 33342染色后行流式细胞仪检测,分选口腔鳞状细胞癌中的SP细胞和非SP细胞,进行体外培养、长期分化和体内成瘤实验,对2种亚群细胞的体内和体外生物学特性进行检测和比较。结果:口腔鳞状细胞癌细胞系NTCR中含有9.3%SP细胞,其SP细胞在细胞的增殖能力、自我更新能力及裸鼠体内成瘤能力等方面与干细胞特性相似。结论:SP细胞可以认为是肿瘤干细胞的富集。进一步深入研究,有可能作为口腔鳞癌诊断、治疗和预后的靶标。     

硫利达嗪对肝癌干细胞的杀伤作用研究

硫利达嗪(Thioridazine,THO)在临床上通常用于治疗精神类疾病;近年来,研究发现THO对肿瘤细胞具有杀伤效果,但其对肝癌干细胞的杀伤作用还未曾有报道。肿瘤干细胞在肿瘤的转移、复发及耐药性方面起着十分重要的作用。利用体外悬浮培养富集肿瘤干细胞并检测药物THO对其杀伤效果,并以此评价THO对肿瘤生长的体外抑制效应。通过检测体外悬浮培养肝癌干细胞在肿瘤干细胞相关因子表达、耐药性及细胞周期等方面因素,显示在一定程度上其具备肿瘤干细胞样特征,磷酸化STAT3、NANOG和XIAP表达显著上调,而Albumin表达下调;进一步运用MTT、Western blotting和细胞流式等实验验证了THO对肝癌干细胞具有较强的杀伤效果并能诱导caspase依赖的细胞凋亡,而对分化的肝癌细胞影响较弱;此外,THO和化疗药物盐酸阿霉素(DOX)的联合使用显著增强了其对肝癌干细胞和分化的肝癌细胞的杀伤作用。因此,该结果首次显示THO对肝癌干细胞具有较强的杀伤能力,可能为今后肝癌的临床治疗带来新的希望。     

干细胞疾病模型在肝脏代谢疾病研究和药物研发中的应用

新药研发的失败率之高众所周知,其中一个原因是依靠动物实验获得的临床前数据无法真实反映人类生理情况,不可避免地在药物进入临床试验后产生偏差,最终可能导致研发失利。基于人诱导性多能干细胞(induced pluripotent stem cells,iPSCs)或成体干细胞建立的疾病模型一方面提供了大量的细胞原材料;另一方面,由于iPSCs或成体干细胞可来源于患者,因而可准确模拟疾病的遗传背景。因此,干细胞疾病模型为药物临床前试验提供了更贴近人体生理和病理情况的体外细胞模型。更进一步地,通过建立群体iPSCs细胞库,可在体外细胞培养皿内进行人类遗传学研究,采用全基因组关联研究(genome-wide association study, GWAS)及定量性状基因座(quantitative trait locus, QTL)等方法筛选人群中与疾病、药物敏感性差异、细胞毒性差异相关的易感位点,为特定药物的毒性、易感性人群间差异等提供遗传学基础,进而为后续临床试验中合适的试验人群的招募提供理论依据。因而,干细胞疾病模型可潜在辅助新药研发,提高新药临床前试验的准确率,降低新药研发的周期和成本。本文以肝脏代谢疾病为对象,对干细胞来源的肝脏细胞疾病模型在代谢功能方面的生理机制研究、药物筛选和评估等领域进行综述。     

中胚层细胞谱系研究

深入认识中胚层细胞谱系产生和发育分化过程有助于体外获得大量可用于移植的、有功能的中胚层来源成体干细胞,为基础科学和再生医学治疗提供理论指导。中国科学院战略性科技先导专项"干细胞与再生医学研究"项目内的中胚层研究,以肌肉和血液两个中胚层来源细胞谱系决定为切入点,探讨中胚层细胞谱系在发育分化过程中的重要功能和调控机制,建立成体干细胞体外扩增培养体系,为中胚层来源干细胞的自我更新、迁移增殖和定向分化研究提供重要的理论基础,并为中胚层系统疾病提供治疗靶点和细胞来源。现将对先导项目启动五年来开展的研究内容及其取得的研究成果进行介绍。     

新分离的脂肪来源基质细胞与培养的脂肪干细胞用于肝纤维化治疗的效能比较

目的:比较新分离的脂肪来源基质细胞(f ASC)与脂肪干细胞(ASC)在抗大鼠肝纤维化方面的治疗潜能。方法:利用胶原酶解法获得新鲜分离的f ASC,体外扩增培养获得不同代数的ASC,用流式细胞仪分析不同代数细胞的表型;建立大鼠肝纤维化模型,并将f ASC或ASC用于干细胞移植治疗,通过血液肝功能指标检测、RT-PCR、HE染色和天狼星红染色评价2类细胞的治疗效果。结果:f ASC和ASC均可显著改善肝纤维化的大鼠肝脏功能,二者用于治疗肝脏疾病的疗效相似。结论:在肝脏疾病的脂肪干细胞移植治疗中,应当综合考虑移植的干细胞体外传代次数和治疗效果间的关系。     

肿瘤细胞来源的外泌体与恶性肿瘤的进展及化疗

外泌体是细胞分泌的一种纳米级囊泡结构,在血液、唾液、尿液等多种体液中均有分布.作为一类重要的细胞间通信分子,外泌体含有多种具有生物活性的成分,可通过多种方式在人体中发挥调节作用.目前在多种类型的细胞中均发现外泌体的存在,而肿瘤细胞来源的外泌体由于其本身的特性和功能特点,可通过微环境介导肿瘤细胞的增生、血管形成和免疫耐受,并可通过介导上皮-间质转化（epithelial-mesenchymal transition, EMT）
和胞内药物排斥反应等增加肿瘤细胞的化疗抵抗能力.同时,因其含有肿瘤细胞所分泌的特异性成分,因而可通过对外泌体中相关分子改变的检测,对疾病进行诊断和监测,并可为临床个体化用药提供新思路.     

Stem cell therapy for COVID-19 and other respiratory diseases: Global trends of clinical trials

Respiratory diseases, including coronavirus disease 2019 and chronic obstructive pulmonary disease (COPD), are leading causes of global fatality. There are no effective and curative treatments, but supportive care only. Cell therapy is a promising therapeutic strategy for refractory and unmanageable pulmonary illnesses, as proved by accumulating preclinical studies. Stem cells consist of totipotent, pluripotent, multipotent, and unipotent cells with the potential to differentiate into cell types requested for repair. Mesenchymal stromal cells, endothelial progenitor cells, peripheral blood stem cells, and lung progenitor cells have been applied to clinical trials. To date, the safety and feasibility of stem cell and extracellular vesicles administration have been confirmed by numerous phase I/II trials in patients with COPD, acute respiratory distress syndrome, bronchial dysplasia, idiopathic pulmonary fibrosis, pulmonary artery hypertension, and silicosis. Five routes and a series of doses have been tested for tolerance and advantages of different regimes. In this review, we systematically summarize the global trends for the cell therapy of common airway and lung diseases registered for clinical trials. The future directions for both new clinical trials and preclinical studies are discussed.     

Stem cell therapy for Alzheimer's disease

Alzheimer's disease (AD) is a progressive neurodegenerative disease characterized by memory loss and cognitive impairment. It is caused by synaptic failure and excessive accumulation of misfolded proteins. To date, almost all advanced clinical trials on specific AD-related pathways have failed mostly due to a large number of neurons lost in the brain of patients with AD. Also, currently available drug candidates intervene too late. Stem cells have improved characteristics of self-renewal, proliferation, differentiation, and recombination with the advent of stem cell technology and the transformation of these cells into different types of central nervous system neurons and glial cells. Stem cell treatment has been successful in AD animal models. Recent preclinical studies on stem cell therapy for AD have proved to be promising. Cell replacement therapies, such as human embryonic stem cells or induced pluripotent stem cell–derived neural cells, have the potential to treat patients with AD, and human clinical trials are ongoing in this regard. However, many steps still need to be taken before stem cell therapy becomes a clinically feasible treatment for human AD and related diseases. This paper reviews the pathophysiology of AD and the application prospects of related stem cells based on cell type.     

Menstrual blood stem cells as a potential source for cell therapy

Cell replacement and restorative therapies show great promise for the treatment of various diseases and traumas. Various types of stem cells that are rather different in terms of biological properties are evaluated as potential sources for cell therapy. Mesenchymal stem cells (MSCs) display relatively high proliferative activity and high level of plasticity and can be differentiated not only into cells of mesenchymal lineage, but also neurons. Among the MSC populations, the population of endometrial stem cells, including that present in the menstrual blood, is readily available. In the current review, we analyze the biological properties of the menstrual blood stem cells and the possibilities of using them as a potential source for cell therapy.     

Hierarchy of in vitro sensitivity and resistance of tumor cells to cytotoxic effector cells,cytokines, drugs and toxins

Summary Drug resistance of tumor cells has led to the development of other therapeutic modalities including biological response modifiers, lymphokine-activated killer cells (LAK), and cytokines alone and in combination. The premise of these alternative modalities is that drug resistance can be overcome by other cytotoxic agents or cytotoxic effector cells. However, the relationship between tumor cell sensitivity to these different agents and the cytotoxicity caused by drugs is not known or well understood. Thus, understanding the relationship between these different systems of tumor cell cytotoxicity is essential for optimal therapeutic intervention. To this end, we compared the tumor cell cytotoxicity mediated by recombinant tumor necrosis factor (rTNF), cytotoxic effector cells (natural killer cells, monocytes, LAK cells), chemotherapeutic drugs, and microbial toxins. Human tumor cell lines sensitive and resistant to rTNF or drugs were used to evaluate the effectiveness of the other cytotoxic modalities. Sensitivity was considered as tumor cell cytotoxicity above 15% while resistance refers to that below 10%. Cell lines tested consisted of several histological types such as brain, lung, colon and ovarian tumors. In our experiments, cell lines made resistant to rTNF by coculture were also relatively resistant to unactivated monocytes and their supernatants. These lines were sensitive to all other methods tested including activated monocytes, natural killer and LAK cells, drugs, and toxins. The tumor lines naturally resistant to rTNF were found to have various degrees of sensitivity and resistance to these other systems. Upon the analysis of our data, a pattern emerged that suggested a hierarchy of sensitivity and resistance of the tumor cells to the cytotoxic mechanisms explored. From a majority of cell lines resistant to rTNF to a minority of lines resistant to LAK, we found an interesting gradation of sensitivity and/or resistance to the other cytotoxic modalities employed. The hypothesis of an underlying common mechanism of action within these systems is discussed.Supported in part by grant CA43 121 from the Department of Health and Human services, NIH, and NRSA clinical and fundamental immunology training grant A107 126, NIH (J. S.), and in part by a grant from the Concern Foundation, Los Angeles and a gift from the Boiron Foundation     

Transport ATPases: Structure,Motors, Mechanism and Medicine: A Brief Overview

Today we know there are four different types of ATPases that operate within biological membranes with the purpose of moving many different types of ions or molecules across these membranes. Some of these ions or molecules are transported into cells, some out of cells, and some in or out of organelles within cells. These ATPases span the biological world from bacteria to eukaryotic cells and have become most simply and commonly known as “transport ATPases.” The price that each cell type pays for transport work is counted in molecules of hydrolyzed ATP, a metabolic currency that is itself regenerated by a transport ATPase working in reverse, i.e., the ATP synthase. Four major classes of transport ATPases, the P, V, F, and ABC types are now known. In addition to being involved in many different types of biological/physiological processes, mutations in these proteins also account for a large number of diseases. The purpose of this introductory article to a mini-review series on transport ATPases is to provide the reader with a very brief and focused look at this important area of research that has an interesting history and bears significance to cell physiology, biochemistry, immunology, nanotechnology, and medicine, including drug discovery. The latter involves potential applications to a whole host of diseases ranging from cancer to those that affect bones (osteoporosis), ears (hearing), eyes (macromolecular degeneration), the heart (hypercholesterolemia/cardiac arrest,), immune system (immune deficiency disease), kidney (nephrotoxicity), lungs (cystic fibrosis), pancreas (diabetes and cystic fibrosis), skin (Darier disease), and stomach (ulcers).     

Teeth-derived stem cells: A source for cell therapy

Cell therapy is one of the important therapeutic approaches in the treatment of many diseases such as cancer, degenerative diseases, and cardiovascular diseases. Among various cell types, which could be used as cell therapies, stem cell therapy has emerged as powerful tools in the treatment of several diseases. Multipotent stem cells are one of the main classes of stem cells that could originate from different parts of the body such as bone marrow, adipose, placenta, and tooth. Among several types of multipotent stem cells, tooth-derived stem cells (TDSCs) are associated with special properties such as accessible, easy isolation, and low invasive, which have introduced them as a good source for using in the treatment of several diseases such as neural injuries, liver fibrosis, and Cohrn’s disease. Here, we provided an overview of TDSCs particular stem cells from human exfoliated deciduous teeth and clinical application of them. Moreover, we highlighted molecular mechanisms involved in the regulation of dental stem cells fate.     

皮肤类器官的构建、功能及其应用研究进展

皮肤类器官作为一种新型的类器官模型,不仅能高度模拟皮肤组织的生理结构和功能,更好地在不同体外环境下还原较真实的皮肤生态,还可以应用于皮肤发育研究、皮肤疾病病理研究及药物筛选等领域。在干细胞研究中,皮肤类器官模型可以在特殊的生境下对具有特定功能的皮肤细胞及其附属物进行重建和改造,以弥补现有体外皮肤模型在结构、功能等方面的不足。基于此,皮肤类器官将会在皮肤再生、组织修复、药物筛选及医学美容等方面扮演越来越重要的角色。本文详述了皮肤类器官构建中所参与的细胞来源及近年来的应用,并对未来皮肤类器官的发展与优化做出了展望。