Direct transplantation of uncultured hair‐follicle pluripotent stem (hfPS) cells promotes the recovery of peripheral nerve injury

We previously showed that the stem cell marker nestin is expressed in hair follicle stem cells which suggested their pluripotency. We subsequently showed that the nestin‐expressing hair‐follicle pluripotent stem (hfPS) cells can differentiate in culture to neurons, glial cells, keratinocytes, and other cell types and can promote regeneration of peripheral nerve and spinal cord injuries upon injection to the injured nerve or spinal cord. The location of the hfPS cells has been termed the hfPS cell area (hfPSCA). Previously, hfPS cells were cultured for 1–2 months before transplantation to the injured nerve or spinal cord which would not be optimal for clinical application of these cells for nerve or spinal cord repair, since the patient should be treated soon after injury. In the present study, we addressed this issue by directly using the upper part of the hair follicle containing the hfPSCA, without culture, for injection into the severed sciatic nerve in mice. After injection of hfPSCA, the implanted hfPS cells grew and promoted joining of the severed nerve. The transplanted hfPS cells differentiated mostly to glial cells forming myelin sheaths, which promoted axonal growth and functional recovery of the severed nerve. These results suggest that the direct transplantation of the uncultured upper part of the hair follicle containing the hfPSA is an important method to promote the recovery of peripheral nerve injuries and has significant clinical potential. J. Cell. Biochem. 110: 272–277, 2010. © 2010 Wiley‐Liss, Inc.     

Implanted hair-follicle-associated pluripotent (HAP) stem cells encapsulated in polyvinylidene fluoride membrane cylinders promote effective recovery of peripheral nerve injury

Hair follicle-associated-pluripotent (HAP) stem cells are located in the bulge area of the hair follicle, express the stem-cell marker, nestin, and have been shown to differentiate to nerve cells, glial cells, keratinocytes, smooth muscle cells, cardiac muscle cells, and melanocytes. Transplanted HAP stem cells promote the recovery of peripheral nerve and spinal cord injuries and have the potential for heart regeneration as well. In the present study, we implanted mouse green fluorescent protein (GFP)-expressing HAP stem-cell spheres encapsulated in polyvinylidene fluoride (PVDF)-membrane cylinders into the severed sciatic nerve of immunocompetent and immunocompromised (nude) mice. Eight weeks after implantation, immunofluorescence staining showed that the HAP stem cells differentiated into neurons and glial cells. Fluorescence microscopy showed that the HAP stem cell hair spheres promoted rejoining of the sciatic nerve of both immunocompetent and immunodeficient mice. Hematoxylin and eosin (H&E) staining showed that the severed scatic nerves had regenerated. Quantitative walking analysis showed that the transplanted mice recovered the ability to walk normally. HAP stem cells are readily accessible from everyone, do not form tumors, and can be cryopreserved without loss of differentiation potential. These results suggest that HAP stem cells may have greater potential than iPS or ES cells for regenerative medicine.     

Human hair follicle pluripotent stem (hfPS) cells promote regeneration of peripheral‐nerve injury: An advantageous alternative to ES and iPS cells

The optimal source of stem cells for regenerative medicine is a major question. Embryonic stem (ES) cells have shown promise for pluripotency but have ethical issues and potential to form teratomas. Pluripotent stem cells have been produced from skin cells by either viral‐, plasmid‐ or transposon‐mediated gene transfer. These stem cells have been termed induced pluripotent stem cells or iPS cells. iPS cells may also have malignant potential and are inefficiently produced. Embryonic stem cells may not be suited for individualized therapy, since they can undergo immunologic rejection. To address these fundamental problems, our group is developing hair follicle pluripotent stem (hfPS) cells. Our previous studies have shown that mouse hfPS cells can differentiate to neurons, glial cells in vitro, and other cell types, and can promote nerve and spinal cord regeneration in vivo. hfPS cells are located above the hair follicle bulge in what we have termed the hfPS cell area (hfPSA) and are nestin positive and keratin 15 (K‐15) negative. Human hfPS cells can also differentiate into neurons, glia, keratinocytes, smooth muscle cells, and melanocytes in vitro. In the present study, human hfPS cells were transplanted in the severed sciatic nerve of the mouse where they differentiated into glial fibrillary‐acidic‐protein (GFAP)‐positive Schwann cells and promoted the recovery of pre‐existing axons, leading to nerve generation. The regenerated nerve recovered function and, upon electrical stimulation, contracted the gastrocnemius muscle. The hfPS cells can be readily isolated from the human scalp, thereby providing an accessible, autologous and safe source of stem cells for regenerative medicine that have important advantages over ES or iPS cells. J. Cell. Biochem. 107: 1016–1020, 2009. © 2009 Wiley‐Liss, Inc.     

Long-Term Extensive Ectopic Hair Growth on the Spinal Cord of Mice from Transplanted Whisker Follicles

We have previously demonstrated that hair follicles contain nestin-expressing pluripotent stem cells that can effect nerve and spinal cord repair upon transplantation. In the present study, isolated whisker follicles from nestin-driven green fluorescent protein (ND-GFP) mice were histocultured on Gelfoam for 3 weeks for the purpose of transplantation to the spinal cord to heal an induced injury. The hair shaft was cut off from Gelfoam-histocultured whisker follicles, and the remaining part of the whisker follicles containing GFP-nestin expressing pluripotent stem cells were transplanted into the injured spinal cord of nude mice, along with the Gelfoam. After 90 days, the mice were sacrificed and the spinal cord lesion was observed to have healed. ND-GFP expression was intense at the healed area of the spinal cord, as observed by fluorescence microscopy, demonstrating that the hair follicle stem cells were involved in healing the spinal cord. Unexpectedly, the transplanted whisker follicles sprouted out remarkably long hair shafts in the spinal cord during the 90 days after transplantation of Gelfoam whisker histocultures to the injured spine. The pigmented hair fibers, grown from the transplanted whisker histocultures, curved and enclosed the spinal cord. The unanticipated results demonstrate the great potential of hair growth after transplantation of Gelfoam hair follicle histocultures, even at an ectopic site.     

Real-time confocal imaging of trafficking of nestin-expressing multipotent stem cells in mouse whiskers in long-term 3-D histoculture

We have previously demonstrated that nestin-expressing multipotent hair follicle stem cells are located above the hair follicle bulge and can differentiate into neurons and other cell types in vitro. The nestin-expressing hair follicle stem cells promoted the recovery of pre-existing axons when they were transplanted to the severed sciatic nerve or injured spinal cord. We have also previously demonstrated that the whisker hair follicle contains nestin-expressing stem cells in the dermal papilla (DP) as well as in the bulge area (BA), but that their origin is in the BA. In the present study, we established the technique of long-term Gelfoam? histoculture of whiskers isolated from transgenic mice in which nestin drives green fluorescent protein (ND-GFP). Confocal imaging was used to monitor ND-GFP-expressing stem cells trafficking in real time between the BA and DP to determine the fate of the stem cells. It was observed over a 2-week period that the stem cells trafficked from the BA toward the DP area and extensively grew out onto Gelfoam? forming nerve-like structures. This new method of long-term histoculture of whiskers from ND-GFP mice will enable the extensive study of the behavior of nestin-expressing multipotent stem cells of the hair follicle.     

The bulge area is the major hair follicle source of nestin-expressing pluripotent stem cells which can repair the spinal cord compared to the dermal papilla

Nestin has been shown to be expressed in the hair follicle, both in the bulge area (BA) as well as the dermal papilla (DP). Nestin-expressing stem cells of both the BA and DP have been previously shown to be pluripotent and be able to form neurons and other non-follicle cell types. The nestin-expressing pluripotent stem cells from the DP have been termed skin precursor or SKP cells. The objective of the present study was to determine the major source of nestin-expressing pluripotent stem cells in the hair follicle and to compare the ability of the nestin-expressing pluripotent stem cells from the BA and DP to repair spinal cord injury. Transgenic mice in which the nestin promoter drives GFP (ND-GFP) were used in order to observe nestin expression in the BA and DP. Nestin-expressing DP cells were found in early and middle anagen. The BA had nestin expression throughout the hair cycle and to a greater extent than the DP. The cells from both regions had very long processes extending from them as shown by two-photon confocal microscopy. Nestin-expressing stem cells from both areas differentiated into neuronal cells at high frequency in vitro. Both nestin-expressing DP and BA cells differentiated into neuronal and glial cells after transplantation to the injured spinal cord and enhanced injury repair and locomotor recovery within four weeks. Nestin-expressing pluripotent stem cells from both the BA and DP have potential for spinal cord regeneration, with the BA being the greater and more constant source.     

Nestin-Expressing Stem Cells Promote Nerve Growth in Long-Term 3-Dimensional Gelfoam?-Supported Histoculture

We have previously reported that hair follicles contain multipotent stem cells which express nestin. The nestin-expressing cells form the hair follicle sensory nerve. In vitro, the nestin-expressing hair follicle cells can differentiate into neurons, Schwann cells, and other cell types. In the present study, the sciatic nerve was excised from transgenic mice in which the nestin promoter drives green fluorescent protein (ND-GFP mice). The ND-GFP cells of the sciatic nerve were also found to be multipotent as the ND-GFP cells in the hair follicle. When the ND-GFP cells in the mouse sciatic nerve cultured on Gelfoam® and were imaged by confocal microscopy, they were observed forming fibers extending the nerve. The fibers consisted of ND-GFP-expressing spindle cells, which co-expressed the neuron marker β-III tubulin, the immature Schwann-cell marker p75^NTR and TrkB which is associated with neurons. The fibers also contain nestin-negative spherical cells expressing GFAP, a Schwann-cell marker. The β-III tubulin-positive fibers had growth cones on their tips expressing F-actin, indicating they are growing axons. When the sciatic nerve from mice ubiquitously expressing red fluorescent protein (RFP) was co-cultured on Gelfoam® with the sciatic nerve from ND-GFP transgenic mice, the interaction of nerves was observed. Proliferating nestin-expressing cells in the injured sciatic nerve were also observed in vivo. Nestin-expressing cells were also observed in posterior nerves but not in the spinal cord itself, when placed in 3-D Gelfoam® culture. The results of the present report suggest a critical function of nestin-expressing cells in peripheral nerve growth and regeneration.     

Multipotent nestin-expressing stem cells capable of forming neurons are located in the upper,middle and lower part of the vibrissa hair follicle

We have previously demonstrated that the neural stem-cell marker nestin is expressed in hair follicle stem cells. Nestin-expressing cells were initially identified in the hair follicle bulge area (BA) using a transgenic mouse model in which the nestin promoter drives the green fluorescent protein (ND-GFP). The hair-follicle ND-GFP-expressing cells are keratin 15-negative and CD34-positive and could differentiate to neurons, glia, keratinocytes, smooth muscle cells and melanocytes in vitro. Subsequently, we showed that the nestin-expressing stem cells could affect nerve and spinal cord regeneration after injection in mouse models. In the present study, we separated the mouse vibrissa hair follicle into three parts (upper, middle and lower). Each part of the follicle was cultured separately in DMEM-F12 containing B-27 and 1% methylcellulose supplemented with basic FGF. After 2 mo, the nestin-expressing cells from each of the separated parts of the hair follicle proliferated and formed spheres. Upon transfer of the spheres to RPMI 1640 medium containing 10% FBS, the nestin-expressing cells in the spheres differentiated to neurons, as well as glia, keratinocytes, smooth muscle cells and melanocytes. The differentiated cells were produced by spheres which formed from nestin-expressing cells from all segments of the hair follicle. However, the differentiation potential is greatest in the upper part of the follicle. This result is consistent with trafficking of nestin-expressing cells throughout the hair follicle from the bulge area to the dermal papilla that we previously observed. The nestin-expressing cells from the upper part of the follicle produced spheres in very large amounts, which in turn differentiated to neurons and other cell types. The results of the present study demonstrate that multipotent, nestin-expressing stem cells are present throughout the hair follicle and that the upper part of the follicle can produce the stem cells in large amounts that could be used for nerve and spinal cord repair.     

The role of hair follicle nestin‐expressing stem cells during whisker sensory‐nerve growth in long‐term 3D culture

We have previously reported that nestin‐expressing hair follicle stem cells can differentiate into neurons, Schwann cells, and other cell types. In the present study, vibrissa hair follicles, including their sensory nerve stump, were excised from transgenic mice in which the nestin promoter drives green fluorescent protein (ND‐GFP mice), and were placed in 3D histoculture supported by Gelfoam®. β‐III tubulin‐positive fibers, consisting of ND‐GFP‐expressing cells, extended up to 500 µm from the whisker nerve stump in histoculture. The growing fibers had growth cones on their tips expressing F‐actin. These findings indicate that β‐III tubulin‐positive fibers elongating from the whisker follicle sensory nerve stump were growing axons. The growing whisker sensory nerve was highly enriched in ND‐GFP cells which appeared to play a major role in its elongation and interaction with other nerves in 3D culture, including the sciatic nerve, the trigeminal nerve, and the trigeminal nerve ganglion. The results of the present report suggest a major function of the nestin‐expressing stem cells in the hair follicle is for growth of the follicle sensory nerve. J. Cell. Biochem. 114: 1674–1684, 2013. © 2013 Wiley Periodicals, Inc.     

Multipotent nestin-expressing stem cells capable of forming neurons are located in the upper,middle and lower part of the vibrissa hair follicle

We have previously demonstrated that the neural stem-cell marker nestin is expressed in hair follicle stem cells. Nestin-expressing cells were initially identified in the hair follicle bulge area (BA) using a transgenic mouse model in which the nestin promoter drives the green fluorescent protein (ND-GFP). The hair-follicle ND-GFP-expressing cells are keratin 15-negative and CD34-positive and could differentiate to neurons, glia, keratinocytes, smooth muscle cells and melanocytes in vitro. Subsequently, we showed that the nestin-expressing stem cells could affect nerve and spinal cord regeneration after injection in mouse models. In the present study, we separated the mouse vibrissa hair follicle into three parts (upper, middle and lower). Each part of the follicle was cultured separately in DMEM-F12 containing B-27 and 1% methylcellulose supplemented with basic FGF. After 2 mo, the nestin-expressing cells from each of the separated parts of the hair follicle proliferated and formed spheres. Upon transfer of the spheres to RPMI 1640 medium containing 10% FBS, the nestin-expressing cells in the spheres differentiated to neurons, as well as glia, keratinocytes, smooth muscle cells and melanocytes. The differentiated cells were produced by spheres which formed from nestin-expressing cells from all segments of the hair follicle. However, the differentiation potential is greatest in the upper part of the follicle. This result is consistent with trafficking of nestin-expressing cells throughout the hair follicle from the bulge area to the dermal papilla that we previously observed. The nestin-expressing cells from the upper part of the follicle produced spheres in very large amounts, which in turn differentiated to neurons and other cell types. The results of the present study demonstrate that multipotent, nestin-expressing stem cells are present throughout the hair follicle and that the upper part of the follicle can produce the stem cells in large amounts that could be used for nerve and spinal cord repair.     

Elongation of mouse spinal cord axons in isogenic grafts of the sciatic nerve, skeletal muscle and submaxillary gland

Isografts of sciatic nerve, skeletal muscle, submaxillary gland and, as control experiments, of optice nerve, were transplanted into the non transected spinal cord of young albino mice, through a punctiform pial aperture. Under these conditions, local cellular reactions were reduced and the sensori motor behavior of the operated animals remained apparently undisturbed throughout the experimental period. Within a few days, axonal sprouts issuing mainly from the terminal clubs of intraspinal nerve fibres severed by the grafting procedure were seen elongating and growing into--and presumably throughout--the nervous as well as the muscular and glandular transplants. The Schwann cells of these grafts, either sedentary or migrating towards the cord and intermingling with host reactive glial cells, appeared to guide the growth of the axonal sprouts they ensheathed (from day 3 to day 10) and generally myelinated (as early as day 6). Optic nerve transplants, lacking Schwann cells, were never reinnervated. Furthermore, in control microinjuries without grafting, limited growth of axonal sprouts was observed only when a few host Schwann cells were present. Mouse spinal neurons, therefore, demonstrate a marked capacity for regrowth when minimal damage to the spinal cord is associated with an adequate supply of Schwann cells. In contrast, host as well as transplanted glial cells, were unable, at least when they were not associated with Schwannian elements, to promote regenerative expression of these central neurons.     

Embryonic stem cell-derived L1 overexpressing neural aggregates enhance recovery after spinal cord injury in mice

An obstacle to early stem cell transplantation into the acutely injured spinal cord is poor survival of transplanted cells. Transplantation of embryonic stem cells as substrate adherent embryonic stem cell-derived neural aggregates (SENAs) consisting mainly of neurons and radial glial cells has been shown to enhance survival of grafted cells in the injured mouse brain. In the attempt to promote the beneficial function of these SENAs, murine embryonic stem cells constitutively overexpressing the neural cell adhesion molecule L1 which favors axonal growth and survival of grafted and imperiled cells in the inhibitory environment of the adult mammalian central nervous system were differentiated into SENAs and transplanted into the spinal cord three days after compression lesion. Mice transplanted with L1 overexpressing SENAs showed improved locomotor function when compared to mice injected with wild-type SENAs. L1 overexpressing SENAs showed an increased number of surviving cells, enhanced neuronal differentiation and reduced glial differentiation after transplantation when compared to SENAs not engineered to overexpress L1. Furthermore, L1 overexpressing SENAs rescued imperiled host motoneurons and parvalbumin-positive interneurons and increased numbers of catecholaminergic nerve fibers distal to the lesion. In addition to encouraging the use of embryonic stem cells for early therapy after spinal cord injury L1 overexpression in the microenvironment of the lesioned spinal cord is a novel finding in its functions that would make it more attractive for pre-clinical studies in spinal cord regeneration and most likely other diseases of the nervous system.     

Human hair-follicle associated pluripotent (hHAP) stem cells differentiate to cardiac-muscle cells

We have previously demonstrated that nestin-expressing hair follicle-associated-pluripotent (HAP) stem cells are located in the bulge area. HAP stem cells have been previously shown to differentiate to neurons, glial cells, keratinocytes, smooth-muscle cells, melanocytes and cardiac-muscle cells in vitro. Subsequently, we demonstrated that HAP stem cells could effect nerve and spinal cord regeneration in mouse models, differentiating to Schwann cells and neurons. In previous studies, we established an efficient protocol for the differentiation of cardiac-muscle cells from mouse HAP stem cells. In the present study, we isolated the upper part of human hair follicles containing human HAP (hHAP) stem cells. The upper parts of human hair follicles were suspended in DMEM containing 10% FBS where they differentiated to cardiac-muscle cells as well as neurons, glial cells, keratinocytes and smooth-muscle cells. This method is appropriate for future use with human hair follicles to produce hHAP stem cells in sufficient quantities for future heart, nerve and spinal cord regeneration in the clinic.     

The bulge area is the origin of nestin-expressing pluripotent stem cells of the hair follicle

Nestin-expressing pluripotent stem cells have been found both in the bulge area (BA) as well as the dermal papilla (DP). Nestin-expressing stem cells of both the BA and DP have been previously shown to be able to form neurons and other non-follicle cell types. The nestin-expressing stem cells from the DP have been termed skin precursor or SKP cells. Both nestin-expressing DP and BA cells have been previously shown to effect repair of the injured spinal cord and peripheral nerve, with the BA being the greater and more constant source of the stem cells. The BA contains nestin-expressing stem cells throughout the hair cycle, whereas nestin-expressing dermal papillae stem cells were found in early and mid-anagen only. Our previous studies have shown that the nestin-expressing stem cells in the BA and DP have similar morphological features. The cells from both regions have a small body diameter of approximately 7 μm with long extrusions, as shown by 2-photon imaging. In the present study, using 2-photon imaging of whisker follicles from transgenic mice expressing nestin-driven green fluorescent protein (ND-GFP), we demonstrate that the BA is the source of the nestin-expressing stem cells of the hair follicle. The nestin-expressing stem cells migrate from the BA to the DP as well as into the surrounding skin tissues including the epidermis, and during wound healing, suggesting that the BA may be the source of the stem cells of the skin itself.     

Interaction of olfactory ensheathing cells with astrocytes may be the key to repair of tract injuries in the spinal cord: The ‘pathway hypothesis’

Transplantation of cultured adult olfactory ensheathing cells has been shown to induce anatomical and functional repair of lesions of the adult rat spinal cord and spinal roots. Histological analysis of olfactory ensheathing cells, both in their normal location in the olfactory nerves and also after transplantation into spinal cord lesions, shows that they provide channels for the growth of regenerating nerve fibres. These channels have an outer, basal lamina-lined surface apposed by fibroblasts, and an inner, naked surface in contact with the nerve fibres. A crucial property of olfactory ensheathing cells, in which they differ from Schwann cells, is their superior ability to interact with astrocytes. When confronted with olfactory ensheathing cells the superficial astrocytic processes, which form the glial scar after lesions, change their configuration so that their outer pial surfaces are reflected in continuity with the outer surfaces of the olfactory ensheathing cells. The effect is to open a door into the central nervous system. We propose that this formation of a bridging pathway may be the crucial event by which transplanted olfactory ensheathing cells allow the innate growth capacity of severed adult axons to be translated into regeneration across a lesion so that functionally valuable connections can be established.     

The adult hair follicle: cradle for pluripotent neural crest stem cells

This review focuses on the recent identification of two novel neural crest-derived cells in the adult mammalian hair follicle, pluripotent stem cells, and Merkel cells. Wnt1-cre/R26R compound transgenic mice, which in the periphery express beta-galactosidase in a neural crest-specific manner, were used to trace neural crest cells. Neural crest cells invade the facial epidermis as early as embryonic day 9.5. Neural crest-derived cells are present along the entire extent of the whisker follicle. This includes the bulge area, an epidermal niche for keratinocyte stem cells, as well as the matrix at the base of the hair follicle. We have determined by in vitro clonal analysis that the bulge area of the adult whisker follicle contains pluripotent neural crest stem cells. In culture, beta-galactosidase-positive cells emigrate from bulge explants, identifying them as neural crest-derived cells. When these cells are resuspended and grown in clonal culture, they give rise to colonies that contain multiple differentiated cell types, including neurons, Schwann cells, smooth muscle cells, pigment cells, chondrocytes, and possibly other types of cells. This result provides evidence for the pluripotentiality of the clone-forming cell. Serial cloning showed that bulge-derived neural crest cells undergo self-renewal, which identifies them as stem cells. Pluripotent neural crest cells are also localized in the back skin hair of adult mice. The bulge area of the whisker follicle is surrounded by numerous Merkel cells, which together with innervating nerve endings form slowly adapting mechanoreceptors that transduce steady skin indentation. Merkel cells express beta-galactosidase in double transgenic mice, which confirms their neural crest origin. Taken together, our data indicate that the epidermis of the adult hair follicle contains pluripotent neural crest stem cells, termed epidermal neural crest stem cells (eNCSCs), and one newly identified neural crest derivative, the Merkel cell. The intrinsic high degree of plasticity of eNCSCs and the fact that they are easily accessible in the skin make them attractive candidates for diverse autologous cell therapy strategies.     

Marrow stromal cells: implications in health and disease in the nervous system

Chronic degenerative diseases and traumatic injuries are responsible for a decline in neuronal function, which often limit life span. While solid organ transplantation such as liver and kidney has been already applied for thousands of patients, great limitation exists in case of nervous system. Cell transplantation is one of the strategies with potential for treatment of such neural disorders, and many kinds of cells including embryonic stem cells and neural stem cells have been considered as candidates for transplantation therapy. Bone marrow stromal cells (MSCs) have great potential as therapeutic agents, since they are easy to isolate and can be expanded from patients without serious ethical and technical problems. We found a method for the highly efficient and specific induction of functional neurons and Schwann cells from both rat and human MSCs. Induced neurons and Schwann cells were transplanted in animal models of Parkinson's disease, stroke, peripheral nerve injury, and spinal cord injury resulting in the successful integration of transplanted cells and improvement in behavior of transplanted animals. Here we focus on the respective potentials of MSC-derived cells and discuss the possibility of clinical application in neurodegenerative and neurotraumatic diseases.     

Presence of transplantable T-lymphoid cells in C57BL/6 mice infected with murine AIDS virus.

The Duplan strain of murine leukemia virus induces murine AIDS in C57BL/6 mice. When spleen cells from C57BL/6 mice infected with the virus were transplanted into nude mice, subcutaneous solid tumors at the transplanted sites were formed and splenomegaly and lymphadenopathy were induced. These transplantable cells were Thy-1- CD4+ alpha-beta T-cell receptor-positive T cells and integrated with the pathogenic defective viral genome. These results indicate that neoplastic cells of T-cell lineage were induced by infecting C57BL/6 mice with murine AIDS virus.     

Olfactory ensheathing cells and repair of brain and spinal cord injuries

Cells generated in cultures of primary tissue from the olfactory nerves can be transplanted into areas of spinal cord damage where they induce growth of severed nerve fibers and return of lost functions. These cells are of two types, both essential for the reparative effect. The precise lineage relationships are not fully understood. The limitation of numbers of cells obtainable from human samples currently restricts their use to repair of small lesions.     

低温保存许旺细胞对周围神经再生的作用

目的：比较原代培养许旺细胞（Schwann cells,SCs)和冷冻保存的SCs移植对损伤后坐骨神经再生的作用。方法：原代培养和液氮保存的SCs分别移植到桥接缺损坐骨神经的硅胶管内。在移植后不同时间（第6和8周末）,硅胶管远端神经干内注射HRP,逆行追踪背根神经节和脊髓前角的标记神经元数量;测量再生神经纤维的复合动作电位传导速度;电镜观察再生神经纤维的髓鞘形成。结果：原代培养和冷冻保存SCs在移植后不同时间其背根神经节和脊髓前角神经元HRP标记细胞数量、再生神经纤维的复合动作电位传导速度基本一致,再生神经纤维髓鞘的形成未见明显差别。结论：冷冻保存的SCs仍具有促进损伤后周围神经再生的能力。