Prolonged life expectancy, life style and environmental changes have caused a changing disease pattern in developed countries towards an increase of degenerative and autoimmune diseases. Stem cells have become a promising tool for their treatment by promoting tissue repair and protection from immune-attack associated damage. Patient-derived autologous stem cells present a safe option for this treatment since these will not induce immune rejection and thus multiple treatments are possible without any risk for allogenic sensitization, which may arise from allogenic stem cell transplantations. Here we report the outcome of treatments with culture expanded human adipose-derived mesenchymal stem cells (hAdMSCs) of 10 patients with autoimmune associated tissue damage and exhausted therapeutic options, including autoimmune hearing loss, multiple sclerosis, polymyotitis, atopic dermatitis and rheumatoid arthritis. For treatment, we developed a standardized culture-expansion protocol for hAdMSCs from minimal amounts of fat tissue, providing sufficient number of cells for repetitive injections. High expansion efficiencies were routinely achieved from autoimmune patients and from elderly donors without measurable loss in safety profile, genetic stability, vitality and differentiation potency, migration and homing characteristics. Although the conclusions that can be drawn from the compassionate use treatments in terms of therapeutic efficacy are only preliminary, the data provide convincing evidence for safety and therapeutic properties of systemically administered AdMSC in human patients with no other treatment options. The authors believe that ex-vivo-expanded autologous AdMSCs provide a promising alternative for treating autoimmune diseases. Further clinical studies are needed that take into account the results obtained from case studies as those presented here.
In the 21st century, live expectancy has rapidly progressed as has the number of previously uncommon diseases with no treatment. Stem cell based therapies are suggested to be able to repair and regenerate tissues in diseases associated with age, changed life style and environmental exposure, such as autoimmune disease and stroke. In particular, mesenchymal stem cells (MSCs) have been applied to treat these diseases . However, the lack of optimized culture protocols for achieving sufficient number of cells, safety issues concerning ex-vivo-expanded cells, the possible reduction in potency of stem cells derived from aged people and patients with autoimmune disease has put into question clinical applications of autologous stem cells in these patients.
In order to apply human autologous adipose tissue derived MSC (hAdMSC) in the clinical setting, we developed a standardized protocol to isolate and culture-expand AdMSC from minimal amounts of fat in vitro, achieving sufficient cell numbers for multiple therapeutic inventions . Expanded AdMSCs maintained the potency for effective differentiation independently of donor age and disease status . The confirmed genetic stability and in vivo safety of ex-vivo-expanded hAdMSCs in animal models and patients  indicate that AdMSCs from older persons are applicable for autologous therapy and are comparable to those derived from young donors . Furthermore, we investigated the migration ability of hAdMSCs and their in vivo homing in animal model after systemic infusion.
MSC include a number of stem cells with an inherent ability for self-renewal and differentiation potential for mesodermal and other embryonic lineages, including adipocytes, osteocytes, chondrocytes, hepatocytes, neurons, muscle cells and epithelial cells , depending on the surrounding microenvironment. A large body of evidence demonstrated that MSC commonly have immunomodulatory and anti-inflammatory properties . While the differentiation properties of MSC seem to dependent on microenvironmental clues in vivo, the immunomodulatory effects appear to be rather intrinsic and thus present an attractive basis for the therapy of autoimmune and inflammatory diseases by systemic infusion. Moreover, intrinsic properties of MSC demonstrated secretion of various factors, modulation of the local environment and activation of endogenous progenitor cells [13, 14]. Hence, MSC therapy evoked therapeutic promises for graft-versus-host disease (GVHD), systemic lupus erythematosus (SLE), rheumatoid arthritis (RA), multiple sclerosis (MS), diabetes, myocardial infarction, thyroditis and different types of neurological disorders, among others .
Various routes of administration of MSCs, including intravenous (i.v.) , intraarterial  or intracerebral  were reported for stem cell application. Of these routes, i.v. is a convenient strategy to deliver cells and therapeutic effects to the injury site. Intravenously injected MSC may be transiently trapped in the lungs, sequestered in the spleen, and are predominantly eliminated by kidneys . Initial accumulation of MSC in the lungs may induce secretion of secondary anti inflammatory effectors .The recent demonstration of in vivo homing properties of bone marrow derived MSCs and AdMSCs has further stimulated i.v. application of MSC for therapy . In this review, we describe several cases of autologous AdMSCs application in autoimmune conditions, including autoimmune hearing loss, MS, polymyotitis (PM), atopic dermatitis (AD) and RA. We suggest that multiple infusions of AdMSC may establish immune homeostasis over long periods of time.
Minimal criteria have been proposed to define MSCs by the Mesenchymal and Tissue Stem Cell Committee of the International Society for Cellular Therapy. These are: 1) plastic adherence ability; 2) lack of hematopoietic markers, such as CD45, CD34, CD14, CD11b, CD79, CD 19, or HLA-DR; 3) tripotential mesodermal differentiation potency into osteoblasts, chondrocytes, and adipocytes; and 4) immunomodulatory capability . In addition to their mesodermal differentiation capability, MSCs were also shown to differentiate in vitro into the ectodermal lineage such as neurons, but also into the endodermal lineage such as myocytes and hepatocytes [7, 31]. The conditions for differentiation of engrafted MSCs in vivo might be more complex and regulated by microenvironmental cluses of local tissues. For example, MSCs engrafted into heart could differentiate into cardiomyocytes, smooth muscle cells, and vascular endothelial cells . In addition, through a series of signals from local tissue, engrafted MSCs can be induced to secrete diverse cytokines that posses trophic and immunomodulatory functions and subsequently contribute to tissue repair and regeneration .
MSC were first isolated as fibroblast colony-forming units (CFU-Fs) or marrow stromal cells from bone marrow (BMMSC) by Friedenstein and colleagues . Their most common name is based on their property of differentiate into a variety of mesodermal tissues including bone, cartilage and fat. MSCs were found in various organs and tissues, including fat, periosteum, synovial membrane, synovial fluid, muscle, dermis, deciduous teeth, pericytes, trabecular bone, infrapatellar fat pad, articular cartilage, umbilical cord and cord blood [36, 37], and placenta .
BMMSCs have first been applied for therapy [39, 40]. However, aspirating BM from the patient is an invasive procedure that yields only low numbers of cells (about 1-10 per 1 105 or 0.0001-0.01% of all BM nucleated cells), requiring high expansion rates . Furthermore, the therapeutic potential of BMMSCs may be diminished with increasing donor age and is associated with declining
differentiation capacity and reduced vitality in vitro . In any case, for autologous transplantation, expanded BMMSCs and AdMSCs have safely been applied in numerous human studies [4, 39, 40].
Adipose tissue is an attractive source of MSCs for autologous stem cell therapy, because adipose tissue is easily obtainable in sufficient quantities using a minimally invasive procedure [23, 43]. In addition, adipose tissues contain more MSCs than BM (about 100, 000 MSCs per gram of fat) . Moreover, differentiation and immunomodulatory potencies of AdMSCs are equivalent to those of BMMSCs .
The efficacy of AdMSCs in treating various diseases has been reported in vivo . Local or systemic administration of AdMSCs was reported to have repair capacity in myocardial infarction  liver injury , hypoxia-ischemia-induced brain damage , allergic rhinitis  and muscular dystrophy . Furthermore, AdMSCs are immune regulatory and potentially suitable to treat immune-related diseases including GVHD , MS , rheumatic disease [17, 18] and thyroditis .
Due to the small number of MSC in tissues, ex vivo expansion is required to generate the cell quantities required to achieve therapeutic results with MSCs through systemic delivery. In case of BMMSCs, however, long-term culture alters the quality of MSCs, including morphological changes, attenuated expression of specific surface markers, reduced proliferative capacity, differentiation potential , and trophic activity .
To produce sufficient numbers of hAdMSCs for stem cell therapy, optimized culture conditions were developed , which allow proliferation of hAdMSC from minimal amounts of fat since large amounts of fat are rarely obtainable from patients suffering from incurable diseases. Usage of a special cannular maximizes survival rate of stem cells in fat tissues and a 3 times higher rate of subsequent early stem cell attachment when compared to other devices. The developed cell collection, cultivation and expansion protocol requires less than 5 g fat to obtain more than 109 cells (after 3 passages). To improve proliferation and differentiation of AdMSC, we tested more than 15 commercially available culture media and eventually developed the hAdMSC culture media, named as RCME (MSC attachment media) and RKCM (MSC proliferation media) . These media provide high viability, shortened doubling times and maintained morphology and improved potency.
The characteristics, stability, toxicity, and tumorigenicity of the culture-expanded hAdMSCs were determined in animals and in human studies . With regard to the safety of culture-expanded stem cells in vitro, genetically stability and consistency on the morphological, immunophenotypic, and differentiation characteristics, as well as toxicity and tumorigenicity need to be verified. We demonstrated that cultured hAdMSCs showed the typical immunophenotype and differentiation capability of MSCs ; cells expressed MSC markers CD90, CD105, CD44 and CD29, but did not express hematopoietic or endothelial markers (CD31, CD34 and CD45) and differentiated to adipogenic, osteogenic, neurogenic, myogeneic and chondrogeneic lineages in vitro. Culture-expanded hAdMSCs were genetically stable for at least 12 passages as determined by karyotype and single nucleotide polymorphism (SNP) assays.
Cells suspended in physiological saline maintained their MSC properties, viability and potency at cold storage conditions (2 to 8C) for at least 72 h, a critical time period for shipping stem cells into the clinic. However, we noticed that physical vibration during shipment might negatively impact cell viability. No evidence of bacterial, fungal, or mycoplasma contamination was observed in cells tested before shipping and cell viability evaluated by trypan blue exclusion was > 95% prior to cell transplantation.
To test the toxicity of hAdMSCs, different cell doses were intravenously injected into immunodeficient severe combined immunodeficiency (SCID) mice, and mice were observed for 13 weeks. Even at the highest cell dose (2.5 108 cells/kg body weight), mice showed no sign of discomfort. Although the safety of i.v. injection of culture expanded autologous and allogenic MSCs has been confirmed in patients  in numerous human clinical studies including osteogenesis imperfect , metachromatic leukodystrophy , acute myocardial infarction  and GVHD , there were some reports presenting that MSCs can induce sarcoma  or facilitate the growth of tumors . In order to test tumorigenicity of hAdMSCs, we performed a tumorigenicity test in Balb/c-nude mice for 26 weeks. Even at the highest cell dose (2 108 MSCs/kg, subcutaneous injection), no evidence of tumor development was found. The safety of hAdMSCs was further investigated in a phase I human clinical trial, with no serious adverse event after i.v. administration of 4 108 hAdMSCs within an observation period of 12 weeks . The minor adverse events found are common to spinal cord injury patients and disappeared spontaneously or were alleviated with medication. One idiopathic case of asymptomatic hyperthyroidism that did not require medical treatment remained sustained during follow-up. Based on these studies, we conclude that the systemic administration of hAdMSCs is safe and does not induce tumor development. In line with these data, Vilalta et al.  reported that hAdMSCs implanted in mice tended to maintain a steady state, and no detectable chromosomal abnormalities or tumors formed during the 8 months of residence in the host's tissues. Notably, the development of sarcoma in the study of Tolar et al was due to cytogenetically abnormal culture-expanded MSCs . In addition, Izadpanah et al.  demonstrated that long-term cultivation of MSC beyond passage 20 may result in their transformation to malignant cells. These results indicate that it is essential to control genetic stability of culture-expanded cells.
Because many diseases that are candidates for stem cells therapy are age-associated degenerative diseases, stem cells obtained from the elderly for autologous use should possess potency in order to have therapeutic effects. In terms of BMMSCs, there have been controversial results regarding the effects of aging. Using human BMMSCs from juveniles and adults seeded onto three-dimensional scaffolds, Mendes et al.  have demonstrated that actual bone formation decreased significantly as patient age increased. Huibregtse et al.  demonstrated that overall reduction in colony-forming efficiency was observed in rabbit BMMSCs derived from older animals. Bergman et al.  demonstrated that differences in basal proliferation rates were observed between young and old BMMSCs isolated from mice, while production of early markers of osteoblastic differentiation in vitro were equivalent. Stenderup et al.  have shown that human BMMSC isolated from older donors have a decreased lifespan and rate of population doubling, while both BMMSCs formed similar amounts of bone both in vitro and in vivo .
Adipose derived MSC seem not to undergo the same senescence pattern as BMMSC [66, 67]. When hAdMSC were derived from elderly (mean 71.4 years) and young donors (mean 36.4 years), cells from both age groups showed similar proliferation, osteogenic differentiation and senescence marker patterns, while BMMSC from the same cohorts showed reduced proliferation, decreased differentiation and increased senescence . In concordance with these findings are data from murine AdMSC derived from senile osteoporotic SAMP6 mice, which showed maintenance of telomere leng
th, telomerase activity and osteogenic differentiation . In order to determine the potency of hAdMSCs isolated from donors aged thirty, forty and fifty, their proliferation and differentiation potential to neural cells was investigated . It was demonstrated that cell number, viability, morphology and neural differentiation potential were not different between hAdMSC of different age and passage. The results suggest that autologous adipose derived stem cells from aged people may be applied for stem cell therapy of age-dependent neural disease with the same stem cell quality and ability as stem cells derived from younger patients.
After i.v. delivery, MSCs are generally found at low or very low frequencies in most target organs, as shown by histology, polymerase chain reaction or by immunohistochemistry . Deak et al.  performed systematic kinetic assessments in non-injury models using enhanced green fluorescent protein transfected murine MSCs. They demonstrated that 24 hr after MSC application, the most frequently positive organs were lungs, liver, kidney, skin, and gut among investigated tissues. In baboons, Devine et al.  demonstrated that high concentration of transplant specific DNA was observed in gastrointestinal tissues. They also showed that kidney, lung, liver, thymus, and skin have relatively high amounts of DNA equivalents. Based on their studies, levels of engraftment in these tissues were estimated, ranging from 0.1 to 2.7%, with similar results with autologous and allogeneic cells . After systemic administration, Lee et al.  found 80% of the infused MSCs in the lungs of mice 15 min after infusion, whereas after 4 days the specific signal for the presence of human MSCs decreased to 0.01%. Of importance, clinical studies with systemically delivered human MSCs did not induce significant intolerance symptoms from the pulmonary or circulatory systems, while murine MSCs displayed a somewhat different behavior. Deak et al.  have demonstrated in a C57BL/6 syngenic murine MSCs transfusion model, that in contrast to human MSCs, murine MSCs home to lungs and might clog in the lungs.
A number of in vivo studies have shown that systemically infused MSCs could migrate to injured, inflamed tissues and exert therapeutic effects [73, 74]. BMMSCs intravenously delivered to rats following myocardial infarction localize in the infarct region and improve ventricular function, while MSCs delivered to non-infarcted rats localize to the BM . Localized abdomen irradiation significantly enhances MSC homing specifically to radiation-injured tissues in mice . A recent study demonstrated the homing properties of i.v. administered hAdMSCs to cell-damaged areas in an allergic rhinitis animal model . The relative organ distribution of fluorescence-labeled hAdMSCs was assessed by us in brain, spinal cord, spleen, thymus, kidney, liver, lung, and heart after i.v. injection in spinal cord injury rats by fluorescence microscopy and human specific Alu PCR. In the injured region of spinal cord, a relatively high percentage of AdMSCs (13%) was found, while most cells remained in spleen (40%) and thymus (21%) [data not shown].
Numerous studies showed the involvement of chemokines or growth factors in MSCs trafficking to the injury region. The interactions of stromal cell-derived factor-1 (SDF-1)- and C-X-C chemokine receptor type 4 (CXCR4) mediated the trafficking of transplanted BMMSCs in a rat model of left hypoglossal nerve injury. In addition, BMMSCs were attracted by chemokines that are presented in the supernatants of primary cultures of human pancreatic islets culture in vitro and in vivo. When we compared soluble factors by in vitro migration assay, platelet derived growth factor (PDGF)-AB and transforming growth factor-1 (TGF-1) were most potent for migration activity of hAdMSCs . hAdMSCs pre-stimulated with tumor necrosis factor (TNF-) showed the highest migration activity. When analyzed by flow cytometry and reverse transcriptase-polymerase chain reaction, hAdMSC expressed C-C chemokine receptor type 1 (CCR1), CCR7, C-X-C chemokine receptor type 4 (CXCR4), CXCR5, CXCR6, EGFR (EGF receptor), FGFR1 (FGF receptor 1), TGFBR2 (TGF receptor 2), TNFRSF1A (TNF receptor 1), PDGFRA (PDGF receptor A) and PDGFRB (PDGF receptor B) at protein and mRNA levels. This study indicates that the migration of hAdMSCs is controlled by various growth factors or chemokines. Hence, modulating the homing capacity of hAdMSCs in vivo could stimulate its migration into injured sites after i.v. administration, and thereby improve their therapeutic potential.
Several characteristics may play a role for the immune regulatory capability and anti-inflammatory effects of MSCs: 1) MSCs have low immunogenicity due to low expression levels of major histocompatibility complex-I (MHC-I) and no expression of MHC-II molecules and costimulatory molecules including B7-1 (CD80), B7-2 (CD86), or CD40 , (2) MSCs secrete soluble factors such as interleukin (IL)-6 and macrophage-colony stimulating factor  and suppress the activation and proliferation of T and B lymphocytes, and interfere with differentiation, maturation and function of dendritic cells, (3) MSC release anti-inflammatory and anti-apoptotic molecules and hence may protect damaged tissues [79, 81].
Due to these properties, MSC transplantation has been used for the treatment of GVHD, and several autoimmune diseases, including autoimmune thyroditis , RA [17, 18] and MS  and implicated for allogeneic stem cell transplantation. Systemic infusion of AdMSCs controlled lethal GVHD in mice transplanted with haploidentical hematopoietic stem cell grafts when the MSCs were injected early after transplantation  although ongoing clinical studies with allogeneic BMMSC were not successful. Therapeutic efficacy of BMMSCs was reported in the animal model of MS . In this experimental autoimmune encephalomyelitis (EAE) model, i.v. infusion of MSCs decreased clinical symptoms when MSCs were injected before or at the onset of the disease. In an experimental collagen-induced arthritis (CIA) study, a single intraperitoneal injection of BMMSCs prevented the occurrence of severe arthritis, and was associated with a decrease in serum levels of pro-inflammatory cytokines . Human AdMSCs have been demonstrated to ameliorate experimental autoimmune thyroiditis via down-regulation of Th1 cytokines . Systemic infusion of hAdMSCs prevented lymphocyte infiltration to thyroid glands, decreased the production of pro-inflammatory cytokines and improved Th1/Th2 balance . MSCs suppressed T-cell proliferation and cytokine production in response to alloantigen and nonspecific antigen, and prolong skin graft survival in vivo . In addition, MSCs inhibit function of B cells , natural killer cells  and dendritic cells . The immunomodulatory function of MSC was mediated both by soluble factors , and by direct cell to cell interactions .
Whether MSC derived from patients with autoimmune diseases will have therapeutic functions after autologous transplantation in a clinical situation is controversial and has not been addressed clinically . Papadaki et al.  showed that while BMMSCs isolated from RA patients were found to be impaired in their ability to support hematopoiesis, BMMSCs isolated from MS patients displayed normal ability [89, 90]. Other data demonstrated that BMMSCs derived from patients with RA, MS, autoimmune SLE, systemic sclerosis (SSc) and Sjogren's syndrome retained their immunomodulatory capabilities in vitro [91, 92].
Given their confirmed in vivo safety and the rationale
that MSCs possess immunomodulatory and anti-inflammatory properties, compassionate-use treatments for autoimmune diseases were initiated in patients after other treatment options were exhausted. All patients provided informed consent to the treatment. Here, we describe treatment of AdMSCs in autoimmune hearing loss (AIED), MS, PM, AD and RA. Details on the patients disease and treatment histories, disease status and treatments are provided in Table
and Additional File
; Case Reports, Table S1 and Figure S1. Additional clinical scores for AD before and after treatment are shown in Table
. Patient analysis was based mostly on clinical parameters. In some cases, immunological and blood status parameters were also measured (cases 3, 4, 5, 8, 9, 10); all cases showed decrease in inflammatory responses and eosinophil counts.
Summary of hAdMSC treatments of 10 patients with different autoimmune-associated diseases.
Autoimmune inner ear disease (AIED)
AIED [93, 94]is a progressive, bilateral yet asymmetric, sensorineural hearing loss. Patients have higher frequencies of interferon (IFN)-c-producing T cells and higher serum antibody titres compared with healthy controls and patients with noise- and/or age-related hearing loss . The mainstay treatment for AIED are anti-inflammatory drugs, particularly corticosteroids [96, 97]. However, some patients are refractory to steroid treatment. Thus, alternative treatment is needed for these patients. Efficacy of hAdMSCs on experimental autoimmune hearing loss (EAHL) was shown in mice . Mice were immunized with -tubulin to develop EAHL and treated with i.v. injection of hAdMSCs (once a week for 6 consecutive weeks) resulting in improved hearing, hair cell stabilization, reduced proliferation of antigen-specific Th1/Th17 cells and induced anti-inflammatory cytokine IL-10 in splenocytes, induction of antigen-specific CD4(+) CD25(+) Foxp3(+) regulatory T-cells with the capacity to suppress autoantigen-specific cytotoxic T-cell responses.
3x each 2 108 (i.v.)
Severe progressing hearing loss for 3 years (no in left ear, severe in right ear)
Normal hearing in right ear, moderate hearing in left ear
Multiple Sclerosis (MS)
MS is a multifocal inflammatory disease of the central nervous system, which mainly affects young women between ages twenty and forty years and causes paralysis of the limbs, sensation, visual and sphincter problems. The disease is clinically evident with relapses of neurological disability due to damage of myelin occurs (plaques of sclerosis). The disease enters a progressive phase due to damage of the axons and irreversible neurodegeneration. Existing immunotherapies downregulate the autoimmune anti-myelin reactivity and reduced the rate of relapses (e.g. INF-, glatiramer acetate and mitoxantrone) but progression of disability and myelin regeneration is not possible [99, 100]. In the chronic EAE animal model , BMMSCs and AdMSCs were shown to restore neuronal activity and produce new neurons [102, 103]. We demonstrated previously that hAdMSCs ameliorates the symptoms in EAE in a dose- and time-dependent manner, and these effects can be mediated in part by the production of anti-inflammatory cytokines .
5x each 1 108 (i.v.)
3x each 1 107 (intrathecal)
PM is a type of chronic inflammatory myopathy with unknown etiology associated with invasion of white blood cells in muscle tissue. PM is related to dermatomyositis and inclusion body myositis. Clinical signs include pain with proximal muscle weakness and loss of muscle mass, particularly in the shoulder and pelvic girdle. Despite the uncertainty in the exact cause of PM, autoimmune, viral, infectious or genetic factors have been suggested. The estimated annual incidence rate is around 5-10 cases/1, 000, 000 in the United States; it increases with age, with the highest rates seen in the 35-44 and 55-64 years. Women are two times more likely to suffer from PM than men. Corticosteroids and immunosuppressant agents are the mainstay of treatment, with a significant percentage of non-responders and clinical relapses . Hematopoietic stem cell transplantation is performed in patients with refractory PM with satisfactory clinical efficacy , but the condition regimen for the procedure has many side effects. Allogeneic MSCs from bone marrow and umbilical cord were transplanted in 10 patients with drug-resistant PM . Although none of the patients stopped immunosuppressive therapy for more than 1-year's follow-up and there was no cure, MSCs treatment may prove to be a useful adjunctive treatment in patients whose disease is poorly controlled with immunosuppressive agents.
4x each 5 108 (i.v.)
inability to walk slope and to stand up by herself
Able to step up stairs (< 10 cm) and walk gentle slope holding handrail
AD is a common, chronic and refractory skin disease manifesting as eczema and pruritus with repeated exacerbations and regressions and unknown pathogenesis . The incidence of AD in adults has increased worldwide over the past decade . Current management aims to relieve frequency of dermal inflammation and prevent its flare-up using topical corticosteroids and tacrolimus [109, 110]. Although these treatments
might control the symptoms, relapse is frequent and extensive and prolonged use of corticosteroid carries risk of side-effects, including skin atrophy and there are many AD patients with corticosteroid phobia . Despite the immunomodulating effect of MSC, there is no previous record of stem cell treatment of AD.
3x each 2 108 (i.v.)
SCORAD index 93.1
SCORAD* index 61.1
3x each 2 108 (i.v.)
SCORAD index 57.0
SCORAD index 35.5
5x each 2 108 (i.v.)
SCORAD index 33.4
SCORAD index 16.4
3x each 2 108 (i.v.)
SCORAD index 39.1
SCORAD index 13.3
RA is a T-cell-mediated systemic autoimmune disease caused by loss of immunologic self tolerance and characterized by synovium inflammation and articular destruction. MSCs were reported to reduce inflammatory and T cell responses and induce antigen specific regulatory T cells in vitro in rheumatoid arthritis . Systemic infusion of hAdMSCs significantly reduced the incidence and severity of experimental arthritis induced by CIA in vivo , which was mediated by down-regulating Th1-driven autoimmune and inflammatory responses and induction of interleukin-10 in lymph nodes and joints. Human AdMSCs also induced de novo generation of antigen-specific CD4+CD25+FoxP3+ Treg cells. The best therapeutic benefits were seen when the stem cell treatments were performed prior to onset and by systemic rather than local application. Recently, the therapeutic effects of systemic infusion human umbilical cord (UC)-MSCs were also verified in the collagen-induced arthritis model with effects similar to those of hAdMSCs.
2x each 3 108 (i.v.)
***VAS score: 10 KWOMAC score: 73
VAS score:2-3 KWOMAC score: 28
Once 2 108
(i.v.) + 1 108
Read the original:
Stem cell treatment for patients with autoimmune disease ...
- Osteoarthritis Treatment - Stem Cell Therapy In India - July 24th, 2016
- MesenCult Mesenchymal Stem Cell Stimulatory Supplements Human - July 24th, 2016
- Mesenchymal Stem Cell Based Therapy for the Treatment of ... - July 23rd, 2016
- visit the mesenchymal cell research webpage - stemcell.com - July 20th, 2016
- Mesenchymal Stromal Cells - July 3rd, 2016
- Immunosuppression by mesenchymal stem cells: mechanisms and ... - July 3rd, 2016
- The Science of Mesenchymal Stem Cells and Regenerative Medicine - July 3rd, 2016
- Prochymal Adult Human Mesenchymal Stem Cells for Treatment ... - July 3rd, 2016
- Mesenchymal Stem Cell Therapy in Multiple System Atrophy ... - July 2nd, 2016
- Mesenchymal Stem Cell-Based Therapy - June 29th, 2016
- Mesenchymal stem cell therapy for treatment of ... - June 5th, 2016
- Stem Cell Treatment - Minnesota Regenerative Medicine - June 1st, 2016
- Stem Cell Therapy for Knee Osteoarthritis and Cartilage ... - June 1st, 2016
- Orthopedic Stem Cell Research and Related Publications - May 5th, 2016
- Stem Cell Injection Treatment for Joint Injuries & Arthritis - May 1st, 2016
- Stem Cell Treatment for Diabetes | Mesenchymal Stem Cell ... - April 28th, 2016
- Human Mesenchymal Stem Cells - bioind.com - April 24th, 2016
- Mesenchymal stem cells - Miltenyi Biotec - April 21st, 2016
- Mesenchymal Stem Cell Therapy for Lung Rejection - Full ... - April 7th, 2016
- Stem cells: What they are and what they do - Mayo Clinic - April 4th, 2016
- Mesenchymal Stem Cell: Keystone of the Hematopoietic Stem ... - April 4th, 2016
- Mesenchymal Stem Cell-Breast Cancer Stem Cell: Relevance to ... - April 4th, 2016
- Clinical applications of mesenchymal stem cells | Journal of ... - April 4th, 2016
- Mesenchymal Stem Cells Market : (2014 to 2020) - Current ... - April 4th, 2016
- Mesenchymal Stem Cells Market Advances and Applications ... - March 22nd, 2016
- Mesenchymal stem cells for cartilage repair in ... - March 21st, 2016
- 10.1186/ar4190 - Arthritis Research & Therapy - March 15th, 2016
- Non-small cell lung cancer cells survived ionizing ... - March 13th, 2016
- Update on mesenchymal stem cell-based therapy in lupus and ... - March 13th, 2016
- Mesenchymal stem cells | Macopharma - March 2nd, 2016
- Research Ready Stem Cell Research Reagents - February 29th, 2016
- Stem Cell Research & Therapy - stemcellres.biomedcentral.com - February 23rd, 2016
- NIH Guide: BASIC RESEARCH ON MESENCHYMAL STEM CELL BIOLOGY - February 22nd, 2016
- Mesenchymal stem cell-based therapy in kidney ... - February 17th, 2016
- Mesenchymal Stem Cells as Therapeutics and Vehicles for ... - February 16th, 2016
- Mesenchymal Stem Cells - Advances & Applications - WDRB 41 ... - February 16th, 2016
- Mesenchymal Stem Cells - Advances & Applications -- LONDON ... - February 16th, 2016
- Mesenchymal stem cells for therapy of pulmonary fibrosis ... - February 16th, 2016
- Mesenchymal Stem Cells - Advances & Applications - WSFA ... - February 16th, 2016
- Stem Cell Research & Therapy | Home page - February 11th, 2016
- Mesenchymal stem cell treatment for chronic renal failure ... - February 7th, 2016
- The therapeutic effect of mesenchymal stem cell ... - February 3rd, 2016
- Umbilical cord mesenchymal stem cell transplantation in ... - January 25th, 2016
- Mesenchymal Stem Cell Therapy - Autonomic Specialists - January 23rd, 2016
- Mesenchymal stem cell therapy in osteoarthritis: advanced ... - January 22nd, 2016
- Molecular Signatures of Mesenchymal Stem Cell-Derived ... - January 21st, 2016
- TRANS.00035 Mesenchymal Stem Cell Therapy For ... - anthem.com - January 21st, 2016
- Duke Stem Cell and Regenerative Medicine Program - January 21st, 2016
- 13th Stem Cell Research & Regenerative Medicine Overview - January 21st, 2016
- CAR T-Cell Immunotherapy for ALL - National Cancer Institute - November 1st, 2015
- Cell Therapy and Regenerative Medicine - October 30th, 2015
- FDA Approves MSC-NP Therapy as Investigational New Drug in ... - October 30th, 2015
- Eli and Edythe Broad Center of Regeneration Medicine and ... - October 28th, 2015
- Cell Therapy Ltd - October 26th, 2015
- A phase I clinical trial of the treatment of Crohn's ... - October 26th, 2015
- Stem Cells in MS : National Multiple Sclerosis Society - October 21st, 2015
- Gene Therapy and Cell Therapy Defined | ASGCT - American ... - October 20th, 2015
- IOVS | Orbital Fibroblasts From Graves' Orbitopathy ... - October 14th, 2015
- Stem Cell Therapy - Premier Stem Cell Institute - October 5th, 2015
- Scaffold-free culture of mesenchymal stem cell spheroids ... - October 3rd, 2015
- Mesenchymal Stem Cells Pge2 - Stem Cell Research - October 2nd, 2015
- Stem Cell Therapy | Cellular Prolotherapy | Caring Medical - September 19th, 2015
- What Is Stem Cell Treatment? | eHow - September 9th, 2015
- Mesenchymal Stem Cell Therapy Trial for Multiple Sclerosis ... - August 7th, 2015
- Mesenchymal Stem Cell Therapy for Inflammatory Bowel ... - August 1st, 2015
- Stem Cell Sciences, Inc. - Stem Cell Research - August 1st, 2015
- Stem cell controversy - Wikipedia, the free encyclopedia - July 23rd, 2015
- Mesenchymal Stem Cells Research Area: R&D Systems - July 12th, 2015
- Allogeneic Mesenchymal Stem Cells for the Treatment of ... - July 9th, 2015
- Application of human mesenchymal and pluripotent stem cell ... - July 6th, 2015
- Mesenchymal Stem Cells Market Forecast and Analysis | Business - July 2nd, 2015
- Stem Cell Research & Therapy | Full text | A therapy-grade ... - June 29th, 2015
- Mesenchymal stem cell treatment for hemophilia: a review ... - June 25th, 2015
- Mesenchymal Stem Cells - Advances & Applications - June 20th, 2015
- Mesenchymal Stem Cells Market - Global Industry Analysis ... - June 19th, 2015
- Stem Cell Therapy | South Florida Orthopedic Surgery - June 4th, 2015
- Mesenchymal Stem Cell Therapy Could Reduce Damaging ... - June 4th, 2015
- Mesenchymal Stem Cell Therapy in the Sports Knee - June 1st, 2015
- The Amazing Mesenchymal Stem Cell | QUANTITATIVE MEDICINE - June 1st, 2015
- Mesenchymal Stem Cell Therapy in Diabetes Mellitus ... - May 17th, 2015