about
Multipotent progenitor cells derived from adult peripheral blood of swine have high neurogenic potential in vitro.Administration of TSG-6 improves memory after traumatic brain injury in mice.Differentiation of nestin‑negative human hair follicle outer root sheath cells into neurons in vitro.Transplanting intact donor tissue enhances dopamine cell survival and the predictability of motor improvements in a rat model of Parkinson's diseaseAutofluorescent cells in rat brain can be convincing impostors in green fluorescent reporter studiesDifferent Tissue-Derived Stem Cells: A Comparison of Neural Differentiation Capability.Stem/progenitor cells from bone marrow decrease neuronal death in global ischemia by modulation of inflammatory/immune responses.Human Mesenchymal Stem Cells Genetically Engineered to Overexpress Brain-derived Neurotrophic Factor Improve Outcomes in Huntington's Disease Mouse Models.Stem cell sources and therapeutic approaches for central nervous system and neural retinal disorders.Motoneuron replacement for reinnervation of skeletal muscle in adult rats.Enrichment of putative stem cells from adipose tissue using dielectrophoretic field-flow fractionationMesenchymal stem cells and their use as cell replacement therapy and disease modelling tool.Stem cell-based therapies for spinal cord injury."Opening" the mesenchymal stem cell tool box.Comparison of MSC-Neurogenin1 administration modality in MCAO rat model.Expression pattern of neurotrophins and their receptors during neuronal differentiation of adipose-derived stem cells in simulated microgravity condition.Critical care of traumatic spinal cord injury.Progress and prospects in neurorehabilitation: clinical applications of stem cells and brain-computer interface for spinal cord lesions.Autologous stem cells in neurology: is there a future?Injury-Induced Neurogenesis: Mechanisms and Relevance.Optogenetics applications for treating spinal cord injury.Hydrogels for central nervous system therapeutic strategies.Transplantation of Defined Populations of Differentiated Human Neural Stem Cell Progeny.Development of a stereotaxic device for low impact implantation of neural constructs or pieces of neural tissues into the mammalian brain.Human stem/progenitor cells from bone marrow enhance glial differentiation of rat neural stem cells: a role for transforming growth factor β and Notch signaling.Angiogenic potential of microvessel fragments is independent of the tissue of origin and can be influenced by the cellular composition of the implants.Differentiation of canine bone marrow stromal cells into voltage- and glutamate-responsive neuron-like cells by basic fibroblast growth factor.Restoration of the striatal circuitry: from developmental aspects toward clinical applications.Comparison of transplant efficiency between spontaneously derived and noggin-primed human embryonic stem cell neural precursors in the quinolinic acid rat model of Huntington's disease.Potential cellular and regenerative approaches for the treatment of Parkinson's disease.70th Birthday symposium of Prof. Dr. Riederer: autologous adult stem cells in ischemic and traumatic CNS disorders.Cell transplantation and gene therapy in Parkinson's disease.Effectiveness of micron-sized superparamagnetic iron oxide particles as markers for detection of migration of bone marrow-derived mesenchymal stromal cells in a stroke model.Enhanced stem cell engraftment and modulation of hepatic reactive oxygen species production in diet-induced obesity.Stem cells in the treatment of chronic spinal cord injury: evaluation of somatosensitive evoked potentials in 39 patients.Effects of labeling human mesenchymal stem cells with superparamagnetic iron oxides on cellular functions and magnetic resonance contrast in hypoxic environments and long-term monitoring
P2860
Q30503659-478A47DC-9A07-46F2-A032-94F7599ADFB6Q30548200-29CC1020-FF5C-4BFA-AA2E-16AE7B9C253BQ33828121-CA1A5E15-0A42-4F57-B62F-EB9E83F853E3Q34442869-DEC96C60-453A-475E-9201-AB8ACE1A20A6Q34997042-D9E9D5F3-2024-4451-AB10-E1ECC7D60746Q35827179-943AE7C1-5A0F-4EFF-9CCB-D99CEBBAF5B3Q36936307-0F48D352-02BE-40C1-8A78-5FC49C83DD29Q36939755-27FBBB71-29F1-4167-A2D2-46FE1A9777DDQ37109618-6FF76F0E-D33A-4021-A1E1-730613077AB3Q37139454-347FD6ED-117D-4790-B040-6F56FEA66391Q37303756-C260C044-7C7B-449C-9CAF-69CDF170BC5CQ37390890-D23FCBD0-A49D-4583-A303-90321E98B5E7Q37537450-9E6BBB6B-1A7F-48AB-95F1-2F266A4AD903Q37597894-F237CE14-DBAE-4A14-B64B-32A3564C3474Q37682331-E55277FE-436C-42AD-8590-E28B2BF55E12Q37683751-3E014080-0B04-40E3-AE07-D6E76784C0B8Q37863948-CD631E13-1D51-4026-9554-013EC55073E3Q38060639-5DBB7AE6-B2E7-4890-8F7A-9E476CE6C7D7Q38062482-CD9EE8B9-2F07-4309-907A-48FA46B297EEQ38292560-F3851530-BFCC-4BFE-A149-E4F8A39938A7Q38435015-787359E8-745B-43FB-9A4B-AFD79BA3D4B3Q38651258-DCBE986E-C2EF-4E71-89BA-97AAC2232BAEQ39709610-0A476C22-C5B7-4E06-B7E6-DB65B97049B0Q41946530-8AD6C99E-BEB4-464B-AB02-85E193EA7D7CQ42031458-495CCDDE-2520-4280-960A-938EB9592218Q42080478-F1300F2E-AACE-4A26-98B5-4B12DFC3B330Q42090118-F9B98791-FEA7-4B3C-81A4-A7EACB62E8A5Q42505344-18F4F7B3-2F6C-4FC6-923A-64927E2C08C0Q43115809-BB25CD14-5936-4E11-A8AA-AE4601AF6EDAQ43198086-593D7E6D-9907-409B-B86C-6AAEBFB9C5F5Q44268910-B6FB1D44-2A91-4B5C-8B17-CD468F701A53Q44297524-1A76E313-51BD-43EB-A874-1B1596937FE8Q46173522-B9895D6A-BCC7-4377-B004-AA62D7335F35Q47914694-37A17D33-2783-4586-B350-D1B17F9221F2Q48681632-08B21956-2A61-412B-8BD7-3DF3463F4592Q59132576-BB6145EC-758B-4F09-987A-E53D610397DF
P2860
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
2007年论文
@zh
2007年论文
@zh-cn
name
Human stem cells for CNS repair.
@en
type
label
Human stem cells for CNS repair.
@en
prefLabel
Human stem cells for CNS repair.
@en
P2860
P50
P1476
Human stem cells for CNS repair
@en
P2093
Rike Zietlow
P2860
P2888
P304
P356
10.1007/S00441-007-0488-1
P577
2007-09-28T00:00:00Z