Process challenges relating to hematopoietic stem cell cultivation in bioreactors

Hematopoietic stem cells (HSCs) are extremely useful in treating a wide range of diseases and have a variety of useful research applications. However, the routinely generated low in vitro concentrations of HSCs from current bioreactor manufacturing systems has been a hindrance to the full-scale application of these essential cellular materials. This has made the search for novel bioreactor systems for high-concentration HSC production a major research endeavour. This review addresses process challenges in relation to bioreactor development and optimisation for high-density HSC production under effective monitoring of essential culture parameters, such as pH, dissolved oxygen and nutrient uptake. It discusses different process strategies and bioreactor configurations for HSCs production from a commercial viability perspective, and also discusses recent advances in the field.     

Global challenges in stem cell research and the many roads ahead

The field of stem cell research has grown to include a vibrant international community of scientists and clinicians who come from both academia and industry and who strive to shed light on the biology of these remarkable cells and find applications in drug discovery, disease modeling, and regenerative medicine.     

Editing human hematopoietic stem cells: advances and challenges

Genome editing of hematopoietic stem and progenitor cells is being developed for the treatment of several inherited disorders of the hematopoietic system. The adaptation of CRISPR-Cas9-based technologies to make precise changes to the genome, and developments in altering the specificity and efficiency, and improving the delivery of nucleases to target cells have led to several breakthroughs. Many clinical trials are ongoing, and several pre-clinical models have been reported that would allow these genetic therapies to one day offer a potential cure to patients with diseases where limited options currently exist. However, there remain several challenges with respect to establishing safety, expanding accessibility and improving the manufacturing processes of these therapeutic products. This review focuses on some of the recent advances in the field of genome editing of hematopoietic stem and progenitor cells and illustrates the ongoing challenges.     

Autologous hematopoietic stem cell transplantation for systemic sclerosis

Systemic sclerosis is a rare disorder manifesting as skin and internal organ fibrosis, a diffuse vasculopathy, inflammation, and features of autoimmunity. Patients with diffuse cutaneous disease or internal organ involvement have a poor prognosis with high mortality. To date no therapy has been shown to reverse the natural course of the disease. Immune suppressive drugs are commonly utilized to treat patients, but randomized trials have generally failed to demonstrate any long-term benefit. In phase I/II trials, autologous hematopoietic stem cell transplantation (HSCT) has demonstrated impressive reversal of skin fibrosis, improved functionality and quality of life, and stabilization of internal organ function, but initial studies were complicated by significant treatment-related mortality. Treatment-related mortality was reduced by better pre-transplant evaluation to exclude patients with compromised cardiac function and by treating patients earlier in disease, allowing selected patients the option of autologous HSCT treatment. There are currently three ongoing randomized trials of autologous HSCT for systemic sclerosis: ASSIST (American Systemic Sclerosis Immune Suppression versus Transplant), SCOT (scleroderma cyclophosphamide versus Transplant), and ASTIS (Autologous Stem cell Transplantation International Scleroderma). The results from these trials should clarify the role of autologous HSCT in the currently limited therapeutic arsenal of severe systemic sclerosis.     

Mesenchymal stem cells in hematopoietic stem cell transplantation

Mesenchymal stromal/stem cells (MSC) of bone marrow (BM) origin not only provide the supportive microenvironmental niche for hematopoietic stem cells (HSC) but are capable of differentiating into various cell types of mesenchymal origin, such as bone, fat and cartilage. In vitro and in vivo data suggest that MSC have low inherent immunogenicity, modulate/suppress immunologic responses through interactions with immune cells, and home to damaged tissues to participate in regeneration processes through their diverse biologic properties. MSC derived from BM are being evaluated for a wide range of clinical applications, including disorders as diverse as myocardial infarction and newly diagnosed diabetes mellitus type 1. However, their use in HSC transplantation, either for enhancement of hematopoietic engraftment or for treatment/prevention of graft-versus-host disease, is far ahead of other indications. Ease of isolation and ex vivo expansion of MSC, combined with their intriguing immunomodulatory properties and their impressive record of safety in a wide variety of clinical trials, make these cells promising candidates for further investigation.     

Cytokines and hematopoietic stem cell mobilization

Hematopoietic stem cell transplantation (HSCT) has become the standard of care for the treatment of many hematologic malignancies, chemotherapy sensitive relapsed acute leukemias or lymphomas, multiple myeloma; and for some non-malignant diseases such as aplastic anemia and immunodeficient states. The hematopoietic stem cell (HSC) resides in the bone marrow (BM). A number of chemokines and cytokines have been shown in vivo and in clinical trials to enhance trafficking of HSC into the peripheral blood. This process, termed stem cell mobilization, results in the collection of HSC via apheresis for both autologous and allogeneic transplantation. Enhanced understanding of HSC biology, processes involved in HSC microenvironmental interactions and the critical ligands, receptors and cellular proteases involved in HSC homing and mobilization, with an emphasis on G-CSF induced HSC mobilization, form the basis of this review. We will describe the key features and dynamic processes involved in HSC mobilization and focus on the key ligand-receptor pairs including CXCR4/SDF1, VLA4/VCAM1, CD62L/PSGL, CD44/HA, and Kit/KL. In addition we will describe food and drug administration (FDA) approved and agents currently in clinical development for enhancing HSC mobilization and transplantation outcomes.     

造血干/细胞研究进展

造血干/祖细胞是具有高度自我更新能力和多向分化潜能的造血前体细胞.从造血干/祖细胞的生物学特性、检测方法、表面标志及体外扩增、定向诱导分化、造血/祖细胞的细胞治疗及基因治疗等几方面进行了综述.     

造血干细胞的研究进展

干细胞研究是一门新兴的学科。经过50多年的努力,造血干细胞的研究已经成为当今生物医学领域中发展最快的领域。介绍了造血干细胞的来源、分离纯化和检测方法以及“可塑性”等方面的研究情况,并详细说明了一些主要的造血干细胞表面标志以及造血干细胞在干细胞移植、细胞治疗和基因治疗等方面的临床应用和前景。     

Dimethyl sulfoxide-free cryopreservation solutions for hematopoietic stem cell grafts

Background aimsThe use of effective methods for the cryopreservation of hematopoietic stem cells (HSCs) is vital to retain the maximum engraftment activity of cord blood units (CBUs). Current protocols entail the use of dimethyl sulfoxide (DMSO) as intracellular cryoprotective agent (CPA) and dextran and plasma proteins as extracellular CPAs, but DMSO is known to be cytotoxic, and its infusion in patients is associated with mild to moderate side effects. However, new, commercially available, DMSO-free cryopreservation solutions have been developed, but their capacity to protect HSCs remains poorly investigated.MethodsHerein the authors compared the capacity of four DMSO-free freezing media to cryopreserve cord blood (CB) HSCs: CryoProtectPureSTEM (CPP-STEM), CryoScarless (CSL), CryoNovo P24 (CN) and Pentaisomaltose (PIM). Clinical-grade DMSO/dextran solution was used as control.ResultsOf the four cryopreservation solutions tested, the best post-thaw cell viability, recovery of viable CD45+ and CD34+ cells and potency were achieved with CPP-STEM, which was equal or superior to that seen with the control DMSO. CSL provided the second best post-thaw results followed by PIM, whereas CN was associated with modest viability and potency. Further work with CPP-STEM revealed that CB CD34-enriched HSCs and progenitors cryopreserved with CPP-STEM maintained high viability and growth expansion activity. In line with this, a pilot transplantation assay confirmed that CPP-STEM-protected CB grafts supported normal short- and long-term engraftment kinetics.ConclusionsThe authors’ results suggest that new, valuable alternatives to DMSO are now available for the cryopreservation of HSCs and grafts, including CBUs.     

Safe and efficient methods of autologous hematopoietic stem cell transplantation for biomedical research in cynomolgus monkeys

We have established safe and efficient methods for autologous hematopoietic stem cell (HSC) transplantation in cynomolgus monkeys (Macaca fascicularis) that include regimens of supportive care to ensure survival during hematopoietic reconstitution following otherwise lethal total body irradiation. Eleven young adult cynomolgus monkeys were studied. Bone marrow was aspirated from the ilium and/or tuber ischiae after administration of recombinant human stem cell factor (SCF) and granulocyte colony-stimulating factor (G-CSF). Using the immunomagnetic selection method, CD34+ cells were then isolated (90 to 95% pure) as a fraction containing HSCs. Just prior to transplantation, the animals received myeloablative total body irradiation-500 to 550 cGy daily for two days. The monkeys re-infused with CD34+ cells developed moderate to severe myelosuppression, with some animals requiring intravenous hyperalimentation, antibiotic administration, and blood transfusion. Hematopoiesis was restored in all animals after transplantation. It took 12 days, on average, until the peripheral white blood cell count reached more than 1,000 cells/microl. Up to two years after transplantation, signs of radiation-induced pneumonitis or other radiation-related disorders were not evident at the aforementioned dose of irradiation. This transplantation model will be useful for testing new approaches using HSCs for therapy of many diseases and will offer unique insights into the biology of these cells.     

The challenges of stem cell therapy

The actual repairing power of stem cells has yet to be fully realized because of insufficient knowledge about the basic mechanisms regulating their fate and unsuitable protocols to implant them in injured tissues. Novel strategies must be formulated to fully exploit stem cell potential in the clinical setting.     

Aspartate availability limits hematopoietic stem cell function during hematopoietic regeneration

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Plasticity after allogeneic hematopoietic stem cell transplantation

The postulated almost unlimited potential of transplanted hematopoietic stem cells (HSCs) to transdifferentiate into cell types that do not belong to the hematopoietic system denotes a complete paradigm shift of the hierarchical hemopoietic tree. In several studies during the last few years, donor cells have been identified in almost all recipient tissues after allogeneic HSC transplantation (HSCT), supporting the theory that any failing organ could be accessible to regenerative cell therapy. However, the putative potential ability of the stem cells to cross beyond lineage barriers has been questioned by other studies which suggest that hematopoietic cells might fuse with non-hematopoietic cells and mimic the appearance of transdifferentiation. Proof that HSCs have preserved the capacity to transdifferentiate into other cell types remains to be demonstrated. In this review, we focus mainly on clinical studies addressing plasticity in humans who underwent allogeneic HSCT. We summarize the published data on non-hematopoietic chimerism, donor cell contribution to tissue repair, the controversies related to the methods used to detect donor-derived non-hematopoietic cells and the functional impact of this phenomenon in diverse specific target tissues and organs.     

Dynamic regulation of hematopoietic stem cell cycling

Comment on: Takizawa H, et al. J Exp Med 2011; 208:273-84.