Cell therapy for Parkinson's disease: Functional role of the host immune response on survival and differentiation of dopaminergic neuroblasts.

Parkinson's disease (PD) is a neurodegenerative disorder, whose cardinal pathology is the loss of dopaminergic neurons in the substantia nigra. Current treatments for PD have side effects in the long term and do not halt disease progression or regenerate dopaminergic cell loss. Attempts to compensate neuronal cell loss by transplantation of dopamine-producing cells started more than 30 years ago, leading to several clinical trials. These trials showed safety and variable efficacy among patients. In addition to variability in efficacy, several patients developed graft-induced dyskinesia. Nevertheless, they have provided a proof of concept that motor symptoms could be improved by cell transplantation. Cell transplantation in the brain presents several immunological challenges. The adaptive immune response should be abolished to avoid graft rejection by the host. In addition, the innate immune response will always be present after transplanting cells into the brain. Remarkably, the innate immune response can have dramatic effects on the survival, differentiation and proliferation of the transplanted cells, but has been hardly investigated. In this review, we analyze data on the functional effects of signals from the innate immune system on dopaminergic differentiation, survival and proliferation. Then, we discussed efforts on cell transplantation in animal models and PD patients, highlighting the immune response and the immunomodulatory treatment strategies performed. The analysis of the available data lead us to conclude that the modulation of the innate immune response after transplantation can increase the success of future clinical trials in PD by enhancing cell differentiation and survival. This article is part of a Special Issue entitled SI: PSC and the brain.

Stem cells for amyotrophic lateral sclerosis modeling and therapy: myth or fact?

Amyotrophic lateral sclerosis (ALS) is a devastating neurodegenerative disease whose pathophysiology is poorly understood. Aiming to better understand the cause of motor neuron death, the use of experimental cell-based models increased significantly over the past years. In this scenario, much knowledge has been generated from the study of motor neurons derived from embryonic stem cells and induced pluripotent stem cells. These methods, however, have advantages and disadvantages, which must be balanced on experimental design. Preclinical studies provide valuable information, making it possible to combine diverse methods to build an expanded knowledge of ALS pathophysiology. In addition to using stem cells as experimental models for understanding disease mechanism, these cells had been quoted for therapy in ALS. Despite ethical issues involved in its use, cell therapy with neural stem cells stands out. A phase I clinical trial was recently completed and a phase II is on its way, attesting the method's safety. In another approach, mesenchymal stromal cells capable of releasing neuroregulatory and anti-inflammatory factors have also been listed as candidates for cell therapy for ALS, and have been admitted as safe in a phase I trial. Despite recent advances, application of stem cells as an actual therapy for ALS patients is still in debate. Here, we discuss how stem cells have been useful in modeling ALS and address critical topics concerning their therapeutic use, such as administration protocols, injection site, cell type to be administered, type of transplantation (autologous vs. allogeneic) among other issues with particular implications for ALS therapy.

Embryonic stem cells improve skeletal muscle recovery after extreme atrophy in mice.

INTRODUCTION: We injected embryonic stem cells into mouse tibialis anterior muscles subjected to botulinum toxin injections as a model for reversible neurogenic atrophy. METHODS: Muscles were exposed to botulinum toxin for 4 weeks and allowed to recover for up to 6 weeks. At the onset of recovery, a single muscle injection of embryonic stem cells was administered. The myofiber cross-sectional area, single twitch force, peak tetanic force, time-to-peak force, and half-relaxation time were determined. RESULTS: Although the stem cell injection did not affect the myofiber cross-sectional area gain in recovering muscles, most functional parameters improved significantly compared with those of recovering muscles that did not receive the stem cell injection. CONCLUSIONS: Muscle function recovery was accelerated by embryonic stem cell delivery in this durable neurogenic atrophy model. We conclude that stem cells should be considered a potential therapeutic tool for recovery after extreme skeletal muscle atrophy.

What do we know about the neurogenic potential of different stem cell types?

Cell therapies, based on transplantation of immature cells, are being considered as a promising tool in the treatment of neurological disorders. Many efforts are being concentrated on the development of safe and effective stem cell lines. Nevertheless, the neurogenic potential of some cell lines, i.e., the ability to generate mature neurons either in vitro or in vivo, is largely unknown. Recent evidence indicate that this potential might be distinct among different cell lines, therefore limiting their broad use as replacement cells in the central nervous system. Here, we have reviewed the latest advancements regarding the electrophysiological maturation of stem cells, focusing our attention on fetal-derived-, embryonic-, and induced pluripotent stem cells. In summary, a large body of evidence supports the biological safety, high neurogenic potential, and in some diseases probable clinical efficiency related to fetal-derived cells. By contrast, reliable data regarding embryonic and induced pluripotent stem cells are still missing.

What do we know about the neurogenic potential of different stem cell types? / O que sabemos sobre o potencial neurogênico de diferentes tipos de células-tronco?

Cell therapies, based on transplantation of immature cells, are being considered as a promising tool in the treatment of neurological disorders. Many efforts are being concentrated on the development of safe and effective stem cell lines. Nevertheless, the neurogenic potential of some cell lines, i.e., the ability to generate mature neurons either in vitro or in vivo, is largely unknown. Recent evidence indicate that this potential might be distinct among different cell lines, therefore limiting their broad use as replacement cells in the central nervous system. Here, we have reviewed the latest advancements regarding the electrophysiological maturation of stem cells, focusing our attention on fetal-derived-, embryonic-, and induced pluripotent stem cells. In summary, a large body of evidence supports the biological safety, high neurogenic potential, and in some diseases probable clinical efficiency related to fetal-derived cells. By contrast, reliable data regarding embryonic and induced pluripotent stem cells are still missing.

Terapias celulares, baseadas no transplante de células imaturas, têm sido consideradas ferramentas promissoras no tratamento de doenças neurológicas. Muitos esforços têm sido concentrados no desenvolvimento de linhas de células-tronco seguras e eficazes. No entanto, o potencial neurogênico de algumas linhagens celulares, ou seja, a habilidade de gerar neurônios maduros, in vitro ou in vivo, ainda é altamente desconhecida. Dados recentes sugerem que esse potencial é distinto entre diversos tipos celulares, o que limitaria o largo emprego como células restauradoras no sistema nervoso central. Neste relato, revisaram-se os avanços recentes relacionados à maturação eletrofisiológica de células-tronco, com foco em células derivadas de tecido fetal, células embrionárias e células pluripotentes induzidas. Em resumo, há evidências que apontam para segurança biológica de células fetais, com alto potencial neurogênico e, em se tratando de algumas doenças, provável eficiência clínica. Ao contrário, ainda não há dados confiáveis acerca de células embrionárias e pluripotentes induzidas.

Transplantation of mouse embryonic stem cell after middle cerebral artery occlusion.

PURPOSE: Stem cell transplantation has been extensively studied as individual therapies for ischemic stroke. The present investigation is an initial effort to combine these methods to achieve increased therapeutic effects after brain ischemia. Cell transplantation may recover massive neuronal loss by replacing damaged brain cells. METHODS: Undifferentiated mouse embryonic stem (mES) cells were used to induce differentiation in vitro into neuron-like cells with good cell viability for use a graft. In this study, middle cerebral artery occlusion (MCAO) was induced in rats using intra-luminal vascular occlusion, and infused mES cells after MCAO. The animals were examined behaviorally using motor and sensory test with neurological assessment. RESULTS: Motor function of the recipients was gradually improved, whereas little improvement was observed in control rats. This result may suggest that the grafted cells have synaptic connection in the recipient brain. Our study revealed that stem cell transplantation can have a positive effect on behavioral recovery and reduction of infarct size in focal ischemic rats. Consequently after euthanasia, rats were histochemically investigated to explore graft survival with green fluorescent protein (GFP). CONCLUSION: The mouse embryonic stem cells may have advantage for use as a donor source in various neurological disorders including motor dysfunction.

Transplantation of mouse embryonic stem cell after middle cerebral artery occlusion / Transplante de células-tronco embrionárias de camundongo após a oclusão da artéria cerebral média

PURPOSE: Stem cell transplantation has been extensively studied as individual therapies for ischemic stroke. The present investigation is an initial effort to combine these methods to achieve increased therapeutic effects after brain ischemia. Cell transplantation may recover massive neuronal loss by replacing damaged brain cells. METHODS: Undifferentiated mouse embryonic stem (mES) cells were used to induce differentiation in vitro into neuron-like cells with good cell viability for use a graft. In this study, middle cerebral artery occlusion (MCAO) was induced in rats using intra-luminal vascular occlusion, and infused mES cells after MCAO. The animals were examined behaviorally using motor and sensory test with neurological assessment. RESULTS: Motor function of the recipients was gradually improved, whereas little improvement was observed in control rats. This result may suggest that the grafted cells have synaptic connection in the recipient brain. Our study revealed that stem cell transplantation can have a positive effect on behavioral recovery and reduction of infarct size in focal ischemic rats. Consequently after euthanasia, rats were histochemically investigated to explore graft survival with green fluorescent protein (GFP). CONCLUSION: The mouse embryonic stem cells may have advantage for use as a donor source in various neurological disorders including motor dysfunction.

OBJETIVO: O transplante de células-tronco tem sido extensivamente estudado como terapias individuais para o AVC isquêmico. A presente investigação é um esforço inicial para combinar estes métodos para alcançar aumento de efeitos terapêuticos após a isquemia cerebral. O transplante de células pode recuperar a perda neuronal intensa, substituindo as células do cérebro danificado. MÉTODOS: Células tronco embrionárias indiferenciadas de camundongo foram utilizadas para induzir in vitro a diferenciação de células como neurônio com boa viabilidade para utilizar como enxerto. Neste estudo foi induzida a oclusão da artéria cerebral média em camundongos, usando a oclusão vascular intraluminal e células embrionárias infundidas. Os animais foram examinados comportamentalmente utilizando motor e teste sensorial com avaliação neurológica. RESULTADOS: A função motora dos receptores melhorou gradualmente, ao passo que pouca melhora foi observada nos animais controle. Este resultado pode sugerir que as células enxertadas têm conexão sináptica no cérebro receptor. Nosso estudo revelou que o transplante de células-tronco pode ter um efeito positivo na recuperação do comportamento e na redução do tamanho do infarto na isquêmica focal em camundongos. Após a eutanásia foi realizada análise histoquímica para avaliar a sobrevida do enxerto com proteína fluorescente verde (GFP). CONCLUSÃO: As células embrionárias de camundongo podem ser utilizadas como enxerto em várias desordens neurológicas, incluindo disfunção motora.

Stem cell therapy for retinal diseases: update.

Distinct stem cell types have been established from embryos and identified in the fetal tissues and umbilical cord blood as well as in specific niches in many adult mammalian tissues and organs such as bone marrow, brain, skin, eyes, heart, kidneys, lungs, gastrointestinal tract, pancreas, liver, breast, ovaries, and prostate. All stem cells are undifferentiated cells that exhibit unlimited self-renewal and can generate multiple cell lineages or more restricted progenitor populations that can contribute to tissue homeostasis by replenishing the cells or to tissue regeneration after injury. The remarkable progress of regenerative medicine in the last few years indicates promise for the use of stem cells in the treatment of ophthalmic disorders. Experimental and human studies with intravitreal bone marrow-derived stem cells have begun. This paper reviews recent advances and potential sources of stem cells for cell therapy in retinal diseases.

Stem cell therapies for type 1 diabetes mellitus.

The present review discusses the use of autologous hematopoietic stem cell transplantation (HSCT) for the treatment of diabetes mellitus type 1 (DM 1). It has been observed that high dose immunosuppression followed by HSCT shows better results among other immunotherapeutic treatments for the disease as the patients with adequate beta cell reserve achieve insulin independence. However, this response is not maintained and reoccurrence of the disease is major a major challenge to use HSCT in future to prevent or control relapse of DM 1.

Establishment of a Brazilian line of human embryonic stem cells in defined medium: implications for cell therapy in an ethnically diverse population.

Pluripotent human embryonic stem (hES) cells are an important experimental tool for basic and applied research, and a potential source of different tissues for transplantation. However, one important challenge for the clinical use of these cells is the issue of immunocompatibility, which may be dealt with by the establishment of hES cell banks to attend different populations. Here we describe the derivation and characterization of a line of hES cells from the Brazilian population, named BR-1, in commercial defined medium. In contrast to the other hES cell lines established in defined medium, BR-1 maintained a stable normal karyotype as determined by genomic array analysis after 6 months in continuous culture (passage 29). To our knowledge, this is the first reported line of hES cells derived in South America. We have determined its genomic ancestry and compared the HLA-profile of BR-1 and another 22 hES cell lines established elsewhere with those of the Brazilian population, finding they would match only 0.011% of those individuals. Our results highlight the challenges involved in hES cell banking for populations with a high degree of ethnic admixture.

Effect of neuronal precursor cells derived from medial ganglionic eminence in an acute epileptic seizure model.

Most of the gamma-aminobutyric acid (GABA)ergic interneurons in the cerebral cortex originate from restricted regions of the ventral telencephalon known as the caudal and medial ganglionic eminence (MGE) and from the preoptic area. It is well established that dysfunction of GABAergic interneurons can lead to epilepsy. During the last decade new approaches to prevent, reduce, or reverse the epileptic condition have been studied, including cell-based therapy from different sources. Recent studies have shown that transplanted neuronal precursor cells derived from MGE have the ability to migrate, differentiate into inhibitory GABAergic interneurons, and integrate into cortical and hippocampal networks, modifying the inhibitory tone in the host brain. Therefore, transplantation of neuronal precursors derived from MGE into the postnatal central nervous system (CNS) could modify the neuronal circuitry in neurologic diseases in which inhibitory synaptic function is altered, such as in epilepsy. Here, we evaluated the seizure susceptibility of mice transplanted with MGE-derived cells in the maximum electroconvulsive shock (MES) model and we review some data from different studies using GABAergic precursor or GABA-releasing cell grafts in animal models of seizure and epilepsy.

Direct myocardial implantation of human fetal stem cells in heart failure patients: long-term results.

BACKGROUND: End-stage heart failure (HF) is refractory to current standard medical therapy, and the number of donor hearts is insufficient to meet the demand for transplantation. Recent studies suggest autologous stem cell therapy may regenerate cardiomyocytes, stimulate neovascularization, and improve cardiac function and clinical status. Although human fetal-derived stem cells (HFDSCs) have been studied for the treatment of a variety of conditions, no clinical studies have been reported to date on their use in treating HF. We sought to determine the efficacy and safety of HFDSC treatment in HF patients. METHODS AND RESULTS: Direct myocardial transplantation of HFDSCs by open-chest surgical procedure was performed in 10 patients with HF due to nonischemic, nonchagasic dilated cardiomyopathy. Before and after the procedure, and with no changes in their preoperative doses of medications (digoxin, furosemide, spironolactone, angiotensin-converting enzyme inhibitors, angiotensin receptor blockers, betablockers), patients were assessed for New York Heart Association (NYHA) class, performance in the exercise tolerance test (ETT), ejection fraction (EF), left ventricular end-diastolic dimension (LVEDD) via transthoracic echocardiography, performance in the 6-minute walk test, and performance in the Minnesota congestive HF test. All 10 patients survived the operation. One patient had a stroke 3 days after the procedure, and although she later recovered, she was unable to perform the follow-up tests. Another male patient experienced pericardial effusion 3 weeks after the procedure. Although it resolved spontaneously, the patient abandoned his control tests and died 5 months after the procedure. An autopsy of the myocardium suggested that new young cells were present in the cardiomyocyte mix. At 40 months, the mean (+/-SD) NYHA class decreased from 3.4 +/- 0.5 to 1.33 +/- 0.5 (P = .001); the mean EF increased 31%, from 26.6% +/- 4% to 34.8% +/- 7.2% (P = .005); and the mean ETT increased 291.3%, from 4.25 minutes to 16.63 minutes (128.9% increase in metabolic equivalents, from 2.46 to 5.63) (P < .0001); the mean LVEDD decreased 15%, from 6.85 +/- 0.6 cm to 5.80 +/- 0.58 cm (P < .001); mean performance in the 6-minute walk test increased by 43.2%, from 251 +/- 113.1 seconds to 360 +/- 0 seconds (P = .01); the mean distance increased 64.4%, from 284.4 +/- 144.9 m to 468.2 +/- 89.8 m (P = .004); and the mean result in the Minnesota test decreased from 71 +/- 27.3 to 6 +/- 5.9 (P < .001). CONCLUSION: Although these initial findings suggest direct myocardial implantation of HFDSCs is feasible and improves cardiac function in HF patients at 40 months, more clinical research is required to confirm these observations.

Embryo biotechnology in dog: a review

Canine embryos are scarce biological material, due to the inefficiency of superovulation and cycle induction/synchronisation protocols. Difficulties encountered in collecting in vivo produced embryos and the impossibility to date to produce canine embryo sin vitro are other limiting factors. In vivo produced embryo transfer procedure is not under control, with only six attempts reported in the literature, leading to the birth of 45 puppies. In vitro, the fertilization rate is particularly low (about 10 %) and the incidence of polyspermy particularly high. So far, no puppy has been obtained from an in vitro produced embryo. In contrast, cloning of somatic cells is successfully used since 4 years with the birth of 41 puppies, with an efficiency not so lower to that obtained in other mammalian species. In the same period, canine embryonic stem sells and transgenic cloned dogs have been obtained. Last generation reproductive technologies are thus in advance over in vitro embryo production. The lack of fundamental studies on the specific features of reproductive physiology and developmental biology in the canine species is regrettable in view of the increasing role of dogs in our society and of the current need for new biological models in biomedical technology.

Embryo biotechnology in dog: a review

Canine embryos are scarce biological material, due to the inefficiency of superovulation and cycle induction/synchronisation protocols. Difficulties encountered in collecting in vivo produced embryos and the impossibility to date to produce canine embryo sin vitro are other limiting factors. In vivo produced embryo transfer procedure is not under control, with only six attempts reported in the literature, leading to the birth of 45 puppies. In vitro, the fertilization rate is particularly low (about 10 %) and the incidence of polyspermy particularly high. So far, no puppy has been obtained from an in vitro produced embryo. In contrast, cloning of somatic cells is successfully used since 4 years with the birth of 41 puppies, with an efficiency not so lower to that obtained in other mammalian species. In the same period, canine embryonic stem sells and transgenic cloned dogs have been obtained. Last generation reproductive technologies are thus in advance over in vitro embryo production. The lack of fundamental studies on the specific features of reproductive physiology and developmental biology in the canine species is regrettable in view of the increasing role of dogs in our society and of the current need for new biological models in biomedical technology. (AU)

[The importance of the use of stem cells for public health]. / A importância do uso das células tronco para a saúde pública.

Stem cells were elected 'Breakthrough of the Year' by Science(1) magazine in 1999, having shown that stem cells from adult tissues retained the ability to differentiate into other tissue types. During the previous year, the first human embryo stem cell lines were established. Since then, the number of scientific papers on stem cells has been increasing exponentially, establishing new paradigms that are rapidly challenged by subsequent experiments. This paper reviews the stem cell research field, divided into two groups: embryo and adult stem cells. While the differentiation potential of the former is well characterized in mice and humans, their use in cell therapy and research has been hampered by histocompatibility, safety and ethical issues. In contrast, adult stem cells do not present these problems. However, the extent of their plasticity is still under investigation. Nevertheless, numerous clinical trials in humans are under way, mainly with stem cells derived from bone marrow. This paper discusses discuss the importance of working with both classes of human stem cells in order to fulfill the promise of stem cell therapies.

Potential role of stem cell therapy in type 1 diabetes mellitus.

Type 1 diabetes mellitus is the result of the autoimmune response against pancreatic beta-cell(s). At the time of clinical diagnosis near 70% of beta-cell mass is been destroyed as a consequence of the auto-destruction that begins months or even years before the clinical diagnosis. Although marked reduction of chronic complications was seen after development and progression of insulin therapy over the years for type 1 diabetic population, associated risks of chronic end-organ damage and hypoglycemia still remain. Besides tight glucose control, beta-cell mass preservation and/or increase are known to be other important targets in management of type 1 diabetes as long as it reduces chronic microvascular complications in the eyes, kidneys and nerves. Moreover, the larger the beta-cell mass, the lower the incidence of hypoglycemic events. In this article, we discuss some insights about beta-cell regeneration, the importance of regulation of the autoimmune process and what is being employed in human type 1 diabetes in regard to stem cell repertoire to promote regeneration and/or preservation of beta-cell mass.

Potencial role of stem cell therapy in type 1 diabetes mellitus: [review]

Type 1 diabetes mellitus is the result of the autoimmune response against pancreatic beta-cell(s). At the time of clinical diagnosis near 70 percent of beta-cell mass is been destroyed as a consequence of the auto-destruction that begins months or even years before the clinical diagnosis. Although marked reduction of chronic complications was seen after development and progression of insulin therapy over the years for type 1 diabetic population, associated risks of chronic end-organ damage and hypoglycemia still remain. Besides tight glucose control, beta-cell mass preservation and/or increase are known to be other important targets in management of type 1 diabetes as long as it reduces chronic microvascular complications in the eyes, kidneys and nerves. Moreover, the larger the beta-cell mass, the lower the incidence of hypoglycemic events. In this article, we discuss some insights about beta-cell regeneration, the importance of regulation of the autoimmune process and what is being employed in human type 1 diabetes in regard to stem cell repertoire to promote regeneration and/or preservation of beta-cell mass.

O diabetes melito tipo 1 (DM1) é o resultado de uma resposta auto-imune contra as células-beta pancreáticas. Por ocasião do diagnóstico clínico do DM1, aproximadamente 70 por cento da massa de células-beta foram destruídas como conseqüência de uma autodestruição que se iniciou há anos ou meses antes dos primeiros sinais da doença. Embora a redução acentuada das complicações crônicas na população com DM1 foi observada após o desenvolvimento e evolução da insulinoterapia, os riscos associados às lesões dos órgãos-alvo e hipoglicemia persistem. Além do controle intensivo da glicemia, a preservação e/ou o aumento da massa de células-beta são reconhecidos como alvos importantes no tratamento do DM1. Isto vem associado à redução das complicações crônicas microvasculares na retina, rins e nervos e a menor incidência de eventos hipoglicêmicos. Neste artigo, discutimos alguns aspectos da regeneração das células-beta pancreáticas, a importância da regulação do processo auto-imune e o que está sendo empregado no DM1 humano com relação ao repertório das células-tronco nesse sentido.