Refractory juvenile idiopathic arthritis: using autologous stem cell transplantation as a treatment strategy

Cellular immune therapy for severe autoimmune diseases can now be considered when such patients are refractory to conventional treatment. The use of autologous stem cell transplantation (ASCT) to treat human autoimmune diseases has been initiated following promising results in a variety of animal models. Anecdotal observations have been made of autoimmune disease remission in patients who have undergone allogeneic bone marrow transplantation as a result of coincidental haematological malignancies. The possibility of inducing immunological self-tolerance by ASCT is particularly attractive as a means for treating juvenile idiopathic arthritis (JIA). In this disease, ASCT restores self-tolerance both through a cell-intrinsic mechanism, involving the reprogramming of autoreactive T cells, and through a cell-extrinsic mechanism, involving a renewal of the immune balance between CD4+CD25+ regulatory T cells and other T cells. This review describes the clinical results of ASCT performed for this disease and the possible underlying immunological mechanisms.     

Cardiac injury protection from mouse bone marrow stromal cells with in utero transplantation followed by secondary postnatal boost

Limited donor-cell engraftment to the injured tissue restricts therapeutic efficacy of stem cell transplantation. Herein, we proposed an alternative strategy by using in utero transplantation (IUT) to create mixed-chimerism environment in recipients and to facilitate donor-cell engraftment followed by postnatal secondary boost with the same cells. Mouse bone marrow stromal cells (BMSCs) were used as the xenogenic donor cells and given into rat fetus as an early exposure of IUT treatment. The engraftment potential was analyzed for the presence of BMSCs by flow cytometry or PCR in recipient tissues. The function of a second boost of mouse BMSCs, in terms of cardioprotection, was tested by given 1×10? cells to rat IUT hearts with ischemia/reperfusion (IR) injury that was induced by a 45 min of left coronary ligation and released for 72 h. Mouse BMSCs demonstrated an immunosuppressive effect when mixed with mouse or rat lymphocytes. IUT treatment only caused few BMSCs engrafted to fetal (embryonic day 20) and adult (4 weeks after birth) rat organs including heart, but engraftment was increased in hearts of the IUT rats after second boost. This was coincided with attenuation of cardiac injury caused by IR. Interestingly, an up-regulation of CXC chemokine receptor type 4 (CXCR4) was seen when BMSCs were exposed to hypoxia. This indicates that enhanced engraftment of mouse BMSCs to post-ischemic rat hearts possibly is dependent on CXCR4. Moreover, results of flow cytometry demonstrated that the presence of CD34? cells in rat IUT hearts with IR injury was increased. These observations suggest that enhanced engraftment of donor BMSCs to rat IR hearts by CXCR4 may recruit endogenous CD34? cells of recipients which in turn protects heart against IR. This also supports the notion of fetal preconditioning with BMSC enhances the efficiency of progenitor cell-mediated organ protection after a postnatal second boost in xeno-transplantation.     

A Mouse Model of in Utero Transplantation

The transplantation of stem cells and viruses in utero has tremendous potential for treating congenital disorders in the human fetus. For example, in utero transplantation (IUT) of hematopoietic stem cells has been used to successfully treat patients with severe combined immunodeficiency.^1,2 In several other conditions, however, IUT has been attempted without success.³ Given these mixed results, the availability of an efficient non-human model to study the biological sequelae of stem cell transplantation and gene therapy is critical to advance this field. We and others have used the mouse model of IUT to study factors affecting successful engraftment of in utero transplanted hematopoietic stem cells in both wild-type mice^4-7 and those with genetic diseases.^8,9 The fetal environment also offers considerable advantages for the success of in utero gene therapy. For example, the delivery of adenoviral¹⁰, adeno-associated viral¹⁰, retroviral¹¹, and lentiviral vectors^12,13 into the fetus has resulted in the transduction of multiple organs distant from the site of injection with long-term gene expression. in utero gene therapy may therefore be considered as a possible treatment strategy for single gene disorders such as muscular dystrophy or cystic fibrosis. Another potential advantage of IUT is the ability to induce immune tolerance to a specific antigen. As seen in mice with hemophilia, the introduction of Factor IX early in development results in tolerance to this protein.¹⁴In addition to its use in investigating potential human therapies, the mouse model of IUT can be a powerful tool to study basic questions in developmental and stem cell biology. For example, one can deliver various small molecules to induce or inhibit specific gene expression at defined gestational stages and manipulate developmental pathways. The impact of these alterations can be assessed at various timepoints after the initial transplantation. Furthermore, one can transplant pluripotent or lineage specific progenitor cells into the fetal environment to study stem cell differentiation in a non-irradiated and unperturbed host environment.The mouse model of IUT has already provided numerous insights within the fields of immunology, and developmental and stem cell biology. In this video-based protocol, we describe a step-by-step approach to performing IUT in mouse fetuses and outline the critical steps and potential pitfalls of this technique.Download video file.^{(55M, mov)}     

Prognostic potential of precise molecular diagnosis of Autosomal Recessive Osteopetrosis with respect to the outcome of bone marrow transplantation

Hematopoietic stem cell transplantation (HSCT) is often the only practical approach to fatal genetic defects. One of the first pathologies which HSCT was applied to was Autosomal Recessive Osteopetrosis (ARO), a rare genetic bone disease in which a deficit in bone resorption by osteoclasts leads to increased bone density and secondary defects. The disease is often lethal early in life unless treated with HSCT. In utero transplantation (IUT) of the oc/oc mouse, reproducing the clinical features of a subset of ARO, has demonstrated that the quality of life and the survival of transplanted animals are greatly improved, suggesting that a similar protocol could be applied to humans. However, recently the dissection of the molecular bases of the disease has shown that ARO is genetically heterogeneous and has revealed the presence of subsets of patients which do not benefit from HSCT. This observation highlights the importance of molecular diagnosing ARO to identify and establish the proper therapies for a better prognosis. In particular, on the basis of experimental results in murine models, efforts should be undertaken to develop approaches such as IUT and new pharmacological strategies.     

同种异体宫内移植小鼠嵌合模型的建立

干细胞宫内移植是一种很有前途的产前治疗方式。为深入研究干细胞移植后的细胞行为,采用宫内移植的方法建立同种异体的嵌合小鼠模型。将雄鼠骨髓单核细胞宫内注射到胎鼠腹腔,在受体鼠出生后检测雌性受体鼠外周血细胞。应用PCR检测外周血是否存在雄性鼠的DNA,并采用定量PCR技术确定其嵌合量;同时用荧光原位杂交（FISH）技术直观观察外周血中雄性来源的细胞。结果表明：共获得4只阳性外周血嵌合小鼠,其中3只稳定嵌合达到6个月以上。应用宫内移植成功建立了外周血中存在异源细胞的小鼠嵌合模型。     

干细胞在妇产科若干疾病中研究及应用

干细胞是一类具有自我更新和增殖分化能力的细胞,按其发育阶段可分为胚胎干细胞(embryonic stem cell,ESC)和成体干细胞(adult stem cell,ASC)。由于干细胞这种特殊的增殖分化潜能,使其具备着多学科临床治疗的可塑性,研究意义巨大。随着子宫内膜干细胞的发现以及对其他类型干细胞提取手段的进步,干细胞为治疗子宫内膜相关性疾病带来了全新的思路。此外,宫内干细胞移植治疗胎儿疾病,干细胞介导损伤后血管内皮的修复以及改善生育功能、治疗不孕症等几个领域的研究也取得了显著的成果。本文参考近7年国内外文献,以干细胞治疗妇产科几种常见疾病的最新研究进展为主要内容进行综述。     

The use of CD 34(+) mobilized peripheral blood as a donor cell source does not improve chimerism after in utero hematopoietic stem cell transplantation in non-human primates

In utero hematopoietic stem cell transplantation is a therapeutic procedure that could potentially cure many developmental diseases affecting the immune and hematopoietic systems. In most clinical and experimental settings of fetal hematopoietic transplantation the level of donor cell engraftment has been low, suggesting that even in the fetus there are significant barriers to donor cell engraftment. In postnatal hematopoietic transplantation donor cells obtained from mobilized peripheral blood engraft more rapidly than cells derived from marrow. We tested the hypothesis that use of donor hematopoietic/stem cells obtained from mobilized peripheral blood would improve engraftment and the level of chimerism after in utero transplantation in non-human primates. Despite the potential competitive advantage from the use of CD 34(+) from mobilized peripheral blood, the level of chimerism was not appreciably different from a group of animals receiving marrow-derived CD 34(+) donor cells. Based on these results, it is unlikely that this single change in cell source will influence the clinical outcome of fetal hematopoietic transplantation.     

Multilineage differentiation of human MSC after in utero transplantation

Prenatal transplantation of stem cells is an exciting frontier for the treatment of many congenital diseases. The fetus may be an ideal recipient for stem cells, as it is immunologically immature and has rapidly proliferating cellular compartments that may support the engraftment of transplanted cells. Mesenchymal stem cells (MSC), given their ability to differentiate among multiple lineages, could potentially be used to treat diseases such as osteogenesis imperfecta, muscular dystrophy, and a variety of others that can be diagnosed in utero. We have shown, using a human-sheep in utero xenotransplantation model, that human MSC have the ability to engraft, differentiate into many tissue types, and survive for over 1 year in fetal lamb recipients. This observation warrants further studies of the behavior of MSC following systemic or site-directed transplantation.     

In utero bone marrow transplantation of fetal baboons with mismatched adult baboon marrow.

In utero bone marrow transplantation to fetuses offers the potential advantage of ameliorating the effects of genetic disorders by transplanting allogeneic hematopoietic stem cells into recipients who are immunoincompetent and require no preparative regimen. Therefore, we undertook studies to examine the feasibility of in utero bone marrow transplantation of unrelated allogeneic adult bone marrow into fetal baboons. Thirty-one baboon fetuses were transplanted between the ages of 60 and 160 days gestation (normal gestation, 182 days) with unrelated allogeneic adult bone marrow containing a different isozyme of glucose-phosphate isomerase (GPI). Approximately one third of the 80-day fetuses demonstrated engraftment 1 month after transplantation. Three of three of the initial chimeras died in utero 45 to 80 days after transplantation and the remaining chimeras lost their graft. Furthermore, 80-day fetal baboons were able to recognize donor cells, maternal cells, and other adult baboon peripheral blood cells in a mixed lymphocyte culture (MLC) reaction but still could engraft with allogeneic bone marrow. In contrast all nonchimeric animals survived to term. These data suggest that fetal transplantation of primates is feasible using techniques employed in these studies and that transplantation of younger fetuses who are immunocompetent should be attempted.     

Feasibility and potential of in utero foetal membrane-derived cell transplantation

Cells isolated from foetal membranes of human term placenta display multiple properties, including some features of stem/progenitor cells, together with immunomodulatory actions and the ability to secrete bioactive soluble factors. Whilst such properties support the potential applicability of these cells in transplantation settings aimed at regenerating/repairing tissues in adults, theoretically, using these cells in prenatal treatment strategies may also be achievable. To assess the feasibility of a foetal membrane-derived cell-based therapeutic treatment during foetal development, we firstly addressed the question of whether in utero transplantation using these cells was possible. To this end, we assessed postnatal microchimerism after transplantation of amniotic membrane-derived cells (a mixture of both mesenchymal stromal/stem cells and epithelial cells) in foetal sheep. Transplantation was performed with or without human umbilical cord blood mononuclear cells and chorionic membrane-derived mesenchymal stromal/stem cells, and was followed by a postnatal booster cell injection. Lambs were euthanized 2–4 months postnatally and their organs/tissues were analysed for microchimerism through detection of human DNA. Human DNA was found in almost all tissues of all of the lambs, with the seemingly random appearance of human cells in some of the analysed tissues suggesting long-term human microchimerism and donor cell migration after in utero/postnatal booster xenotransplation. Differences in microchimerism tissue distribution between animals transplanted with different cell types are discussed. This pilot study adds to ongoing efforts by different investigators to explore the potential of in utero cellular transplantation, and warrants further investigation of using foetal membrane-derived cells for prenatal cell therapies.     

Importance of the stem cell microenvironment for ophthalmological cell-based therapy

Cell therapy is a promising treatment for diseases that are caused by cell degeneration or death. The cells for clinical transplantation are usually obtained by culturing healthy allogeneic or exogenous tissue invitro. However, for diseases of the eye, obtaining the adequate number of cells for clinical transplantation is difficult due to the small size of tissue donors and the frequent needs of long-term amplification of cells in vitro, which results in low cell viability after transplantation. In addition, the transplanted cells often develop fibrosis or degrade and have very low survival. Embryonic stem cells(ESCs) and induced pluripotent stem cells(i PS) are also promising candidates for cell therapy. Unfortunately, the differentiation of ESCs can bring immune rejection, tumorigenicity and undesired differentiated cells, limiting its clinical application. Although i PS cells can avoid the risk of immune rejection caused by ES cell differentiation post-transplantation, the low conversion rate, the risk of tumor formation and the potentially unpredictable biological changes that could occur through genetic manipulation hinder its clinical application. Thus, the desired clinical effect of cell therapy is impaired by these factors. Recent research findings recognize that the reason for low survival of the implanted cells not only depends on the seeded cells, but also on the cell microenvironment, which determines the cell survival, proliferation and even reverse differentiation. When used for cell therapy, the transplanted cells need a specific three-dimensional structure to anchor and specific extra cellular matrix components in addition to relevant cytokine signaling to transfer the required information to support their growth. These structures present in the matrix in which the stem cells reside are known as the stem cell microenvironment. The microenvironment interaction with the stem cells provides the necessary homeostasis for cell maintenance and growth. A large number of studies suggest that to explore how to reconstruct the stem cell microenvironment and strengthen its combination with the transplanted cells are key steps to successful cell therapy. In this review, we will describe the interactions of the stem cell microenvironment with the stem cells, discuss the importance of the stem cell microenvironment for cell-based therapy in ocular diseases, and introduce the progress of stem cell-basedtherapy for ocular diseases.     

Stem cells for spine surgery

In the past few years, stem cells have become the focus of research by regenerative medicine professionals and tissue engineers. Embryonic stem cells, although capable of differentiating into cell lineages of all three germ layers, are limited in their utilization due to ethical issues. In contrast, the autologous harvest and subsequent transplantation of adult stem cells from bone marrow, adipose tissue or blood have been experimentally utilized in the treatment of a wide variety of diseases ranging from myocardial infarction to Alzheimer’s disease. The physiologic consequences of stem cell transplantation and its impact on functional recovery have been studied in countless animal models and select clinical trials. Unfortunately, the bench to bedside translation of this research has been slow. Nonetheless, stem cell therapy has received the attention of spinal surgeons due to its potential benefits in the treatment of neural damage, muscle trauma, disk degeneration and its potential contribution to bone fusion.     

Therapeutic plasticity of stem cells and allograft tolerance

Transplantation is the treatment of choice for many diseases that result in organ failure, but its success is limited by organ rejection. Stem cell therapy has emerged in the last years as a promising strategy for the induction of tolerance after organ transplantation. Here we discuss the ability of different stem cell types, in particular mesenchymal stromal cells, neuronal stem/progenitor cells, hematopoietic stem cells and embryonic stem cells, to modulate the immune response and induce peripheral or central tolerance. These stem cells have been studied to explore tolerance induction to several transplanted organs, such as heart, liver and kidney. Different strategies, including approaches to generating tolerance in islet transplantation, are discussed here.     

骨髓干细胞移植治疗肝硬化的基础与临床研究现状

肝硬化是一种临床常见的肝病良性终末期表现。目前临床上尚缺乏有效的治疗措施。肝脏移植是最理想的治疗方法,但受供体肝脏来源限制,且费用昂贵。近年来开展的自体骨髓干细胞(BMSCs)移植治疗,为肝硬化的治疗带来了新的希望。BMSCs主要包括造型血干细胞和间充质干细胞,其具有可塑性,体外通过生长因子,体内利用特定微环境均可诱导BMSCs分化为肝前体细胞和成熟肝细胞,并明显改善肝功能。从动物实验到临床研究亦表明,BMSCs具有来源丰富、费用低廉、损伤小、自体移植不栓塞、无排斥反应等优点,为治疗肝病带来了新思路,有望成为生物人工肝的细胞来源。本文就BMSCs移植治疗肝硬化的研究现状,尤其是移植途径以及在肝脏内定居、迁移和分化机制的示踪观察方法和存在的问题作一综述,以期为从事肝病研究的同仁提供参考依据。通过对BMSCs移植从基础研究及临床应用的最新进展的描述,展示BMSCs在肝硬化治疗方面良好的治疗前景。     

Unexpected encounter of the parasitic kind

Both parasitology and stem cell research are important disciplines in their own right. Parasites are a real threat to human health causing a broad spectrum of diseases and significant annual rates morbidity and mortality globally. Stem cell research, on the other hand, focuses on the potential for regenerative medicine for a range of diseases including cancer and regenerative therapies. Though these two topics might appear distant, there are some "unexpected encounters". In this review, we summarise the various links between parasites and stem cells. First,we discuss how parasites' own stem cells represent interesting models of regeneration that can be translated to human stem cell regeneration. Second, we explore the interactions between parasites and host stem cells during the course of infection. Third, we investigate from a clinical perspective, how stem cell regeneration can be exploited to help circumvent the damage induced by parasitic infection and its potential to serve as treatment options for parasitic diseases in the future. Finally, we discuss the importance of screening for pathogens during organ transplantation by presenting some clinical cases of parasitic infection following stem cell therapy.     

全身放疗在造血干细胞移植中的研究进展

全身照射疗法(TBI)是一种姑息治疗,该方法已经成功地应用在慢性淋巴细胞白血病或滤泡性淋巴瘤等无干细胞支持的放射敏感的疾病中。目前,在血液系统恶性疾病中造血干细胞移植是较为有效的治疗手段之一,其中全身放射治疗与大剂量化疗是造血干细胞移植疗法的经典预处理方案。TBI方法主要应用在造血移植环境中,具有较强的周期非特异性抗肿瘤效应和免疫抑制效能。TBI给予干细胞移植病人超过正常骨髓的辐射耐受量,通过重建病人的造血和免疫来达到治疗目的。     

In utero hematopoietic cell transplantation—recent progress and the potential for clinical application

In utero hematopoietic stem cell transplantation (IUHCT) is a potential therapeutic alternative to postnatal hematopoietic stem cell transplantation (HSCT) for congenital hematologic disorders that can be diagnosed early in gestation and can be cured by HSCT. The rationale is to take advantage of normal events during hematopoietic and immunologic ontogeny to facilitate allogeneic hematopoietic engraftment. Although the rationale remains compelling, IUHCT has not yet achieved its clinical potential. This review will discuss recent experimental progress toward overcoming the barriers to allogeneic engraftment and new therapeutic strategies that may hasten clinical application.     

Bone marrow transplantation beyond treatment of aplasia and neoplasia.

Marrow transplantation has proved to be an important modality in the treatment of aplastic anemia, acute leukemia, and some other malignant diseases of hemopoietic cells. Much less attention has been paid to the role of marrow transplantation in the treatment of stem cell disorders such as sickle cell disease, chronic granulomatous disease, or Gaucher''s disease. Allogeneic transplantation is successful in these disorders, but carries a considerable risk to the recipient. Autologous transplantation becomes a reality when efficient gene transfer with sustained expression is developed. As methods are developed to harvest hemopoietic stem cells from the peripheral blood and to amplify these cells without causing them to differentiate, transplantation will become increasingly valuable in the treatment of stem cell disorders.     

Fate of amnion-derived stem cells transplanted to the fetal rat brain: migration, survival and differentiation

We have recently characterized a stem cell population isolated from the rodent amniotic membrane termed amnion-derived stem cells (ADSCs). In vitro ADSCs differentiate into cell types representing all three embryonic layers, including neural cells. In this study we evaluated the neuroectodermal potential of ADSCs in vivo after in utero transplantation into the developing rat brain. A clonal line of green fluorescent protein-expressing ADSCs were infused into the telencephalic ventricles of the developing embryonic day 15.5 rat brain. At E17.5 donor cells existed primarily as spheres in the ventricles with subsets fused to the ventricular walls, suggesting a mode of entry into the brain parenchyma. By E21.5 green fluorescent protein (GFP) ADSCs migrated to a number of brain regions. Examination at postnatal time points revealed that donor ADSCs expressed vimentin and nestin. Subsets of transplanted ADSCs attained neuronal morphologies, although there was no immunohistochemical evidence of neural or glial differentiation. Some donor cells migrated around blood vessels and differentiated into putative endothelial cells. Donor ADSCs transplanted in utero were present in recipients into adulthood with no evidence of immunological rejection or tumour formation. Long-term survival may suggest utility in the treatment of disorders where differentiation to a neural cell type is not required for clinical benefit.