Muscle spindle formation and differentiation in regenerating rat muscle grafts

Muscle spindle development and function are dependent upon sensory innervation. During muscle regeneration, both neural and muscular components of spindles degenerate and it is not known whether reinnervation of a regenerating muscle results in reestablishment of proper neuromuscular relationships within spindles or whether sensory neurons may exert an influence upon differentiation of these spindles. Muscle spindle regeneration was studied in bupivacaine-treated grafts of rat extensor digitorum longus (EDL) muscles. Three types of EDL graft were performed in order to manipulate the extent to which regenerating spindles might be reinnervated: (1) grafts reinnervated following severance of their nerve supply (standard grafts); (2) grafts in which intact nerve sheaths appear to facilitate reinnervation (nerveintact grafts); and (3) grafts in which reinnervation was prevented (nonreinnervated grafts). Complete degeneration of muscle fibers occurred in all grafts prior to regeneration. Initial formation of spindles in regenerating EDL grafts is independent of innervation; intrafusal muscle fibers degenerate and regenerate within spindle capsules that remain intact and viable. The extent of spindle differentiation was evaluated in each type of graft using criteria that included nucleation and ATPase activity, both of which have been shown to be regulated by sensory innervation, as well as the number of muscle fibers/spindle and morphology of spindle capsules.While most spindles contained normal numbers of muscle fibers, most of these fibers were morphologically and histochemically abnormal. Alterations of ATPase activity occurred in all spindles, but were least severe in nerve-intact grafts. While fully differentiated nuclear bag and chain fibers were not observed in regenerated spindles, large, vesicular nuclei, similar to those of normal intrafusal fibers, were present in a small number of spindles in nerve-intact grafts. Sensory nerve terminations were observed only in those spindles that also contained the distinctive nuclei. This study suggests that a specific neurotrophic influence is necessary for regeneration of normal intrafusal muscle fibers and that this influence corresponds to the properly timed sensory neuron-muscle interaction which directs muscle spindle embryogenesis. However, the infrequent occurrence of characteristics unique to intrafusal muscle fibers indicates that reinnervation of regenerating muscle grafts by sensory neurons is inadequate and/or faulty.     

The microscopic morphology of orthotopic free muscle grafts in rabbits

The flexor digitorum superficialis muscle was free grafted (without neurovascular anastomoses) in 122 rabbit forelimbs. Histologic nd histochemical examinations through 6 months after grafting were performed. An early ischemic necrosis of the entire graft, except for a few percent of fibers at the very surface, was consistently seen. Subsequently, there occurred a regeneration of muscle with reconstitution of up to 100 percent of normal numbers of fibers. There was a wide variation in the numbers of fibers regenerated; however, the fiber-free areas were then being replaced by connective tissue. Muscle grafts in 1-month-old rabbits regenerated faster and yielded muscle with evidence of more extensive reinnervation and less connective tissue than 3-month-old animals. In the early postgraft period, minced grafts appeared to be as good as whole ones, but after 1 month, they developed far more connective tissue. Differentiation into fast-twitch and slow-twitch muscle fibers and into high- and low-oxidative fibers began at 2 to 3 weeks after grafting but was not extensive until 3 months. At 6 months, grafts showed areas of normal-appearing muscle interspersed with areas that lacked signs of reinnervation. The earliest sign of regeneration is the appearance of several very elongated nuclei encircling each previously anucleate necrotic muscle fiber. A small amount of basophilic cytoplasm then appears around each new nucleus. As blood vessels grow into the graft, a centripetal wave of phagocytosis is seen, taking 2 to 3 weeks and leaving a bed of immature muscle fibers. We believe this to be the first documentation of regeneration's commencing prior to and thus independently of phagocytosis.     

Intrinsic innervation of the uterus in guinea pig and rat

The pattern of distribution of cholinergic and adrenergic nerves in the uterus of albino rats and guinea pigs was examined histochemically. In the albino rat, the uterus was found well-innervated by both adrenergic and cholinergic nerves with a clear regional variation. Dense innervation was demonstrated at the tubal and cervical ends of the uterus and in the cervix. Cholinergic nerves supplying the glands were more numerous than the adrenergic nerves which were relatively few. In the guinea-pigs, the uterus was richly innervated by adrenergic nerves with a clear regional variation. No cholinesterase-positive nerves or nerve cells were demonstrated.     

Nerve regeneration after correction of its defect with a vascularized autologous nerve transplant

In chronic experiment performed on 6 dogs, by means of some neurohistological techniques peculiarities of regeneration of nerves have been studied, when their defects are substituted for vascularized and common autoneurotransplants. When the vascularized autoneurotransplants are applied, more favourable conditions are made for the nerve regeneration, than at a free plastisity and amount of regenerated fibers distal to the graft reaches 34-88%, more often making 48-52% of the initial number of fibers in the proximal parts of the nerves in 3 months after the operation. When in the same animals in the contralateral side common autoneurotransplants have been applied, during the same time the amount of fibers regenerated into the peripheral parts of the nerves makes 10-26%, more often 17-20% from the initial level, or in 2-2.5 times less than at substitution of the defects for the vascularized grafts. Absence of an active cellular reaction of the surrounding tissues to the sutural material supramid is used.     

Sensory reinnervation in microsurgical reconstruction of the heel

Six sensory reinnervation techniques were carried out in 10 patients who underwent reconstruction of the weight-bearing surface of the heel by microsurgical free-tissue transfer. The techniques include the use of neurovascular island flaps, neurosensory flaps, sensory nerve grafts to skin flaps, coaptation of the sensory nerve to the motor nerve of the muscle flaps, direct sensory nerve transfer, and sensory nerve graft transfer. In all patients, some sensation developed, characterized by sensation to light touch, to dull objects, to pinprick, to pain, and to tickling. Three patients developed the ability to distinguish sharp from dull objects and the sensation of pain. The remaining seven had the sensation of touch to various mechanical stimuli. In nine patients, the sensation is located in the weight-bearing surface of the reconstructed heel. Five patients bear weight on the reconstructed surface at least 6 hours per day. Three participate actively in sports. Split-thickness skin graft-muscle flaps were more prone to breakdown than skin flaps. Full-thickness skin flaps appear necessary for the production of pain sensation and the more discriminating sensations. Preliminary results suggest a functional benefit after sensory reinnervation.     

Functional deficits in skeletal muscle grafts

Individual skeletal muscle fibers degenerate and regenerate with minimal functional deficits. When whole skeletal muscles are grafted in rats or cats by standard grafting techniques, revascularization and reinnervation must occur spontaneously. Under these circumstances, contraction times and maximum velocities of shortening eventually return to control values, but a significant deficit is observed in maximum tetanic tension. Grafts made with anastomosis of nerves or with nerves left intact have smaller deficits in tension development than do standard grafts made without nerve repair. The measurement of contractile properties of single motor units in extensor digitorum longus (EDL) muscles and in EDL grafts in rats indicates that the decreased maximum tetanic tension of whole grafts is due to a 10-20% decrease in the maximum tetanic tension of individual motor units, whereas standard grafts also show a 40-45% decrease in the number of motor units. Compared with control values, the fatigability of 100-mg grafts in rats is decreased, whereas larger 3-g grafts in cats show an increased fatigability. The deficits observed in large grafts can be reduced, but not eliminated, by grafting with neurovascular anastomoses.     

Does the nail bed really regenerate?

From observations of nail bed injuries, the regeneration of the nail bed seemed evident. The nail bed regenerated well in the presence of the nail matrix and poorly in its absence, suggesting that the nail bed regenerated from the nail matrix. Full-thickness skin graft or flap coverage of nail bed defects resulted in the good nail bed regeneration. The nail bed grew back, pushing the graft or the flap distally. The regenerated nail beds were about 70 percent of normal size in guillotine-type amputations and about 90 percent in the presence of an intact distal phalanx. The difference between full- and split-thickness skin grafts seemed to be adherence to the phalangeal bone, the former giving way to the advancing nail bed and the latter staying in the way. In addition, the destination of the moving nail bed cells was discussed.     

The clustering of acetylcholine receptors and formation of neuromuscular junctions in regenerating mammalian muscle grafts

The present investigation was undertaken to study the relationship between acetylcholine receptor (AchR) clustering and endplate formation within regenerating skeletal muscle grafts. Silver staining of nerves was combined with rhodamine-alpha-bungarotoxin labeling of AchR clusters in heterotopic grafts of the rat soleus muscle. Two major graft procedures were used: whole muscle grafts and grafts which lacked the zone of original motor endplates (MEP-less grafts). These categories were subdivided into standard grafts, where subsequent innervation was allowed, and noninnervated grafts, which were experimentally deprived of innervation. Grafting brought about the death and removal of muscle fibers, followed by regeneration of myotubes within surviving basal lamina sheaths. A transient population of small extra-junctional AchR clusters spontaneously appears shortly after myotube formation in all four muscle graft types. Early myotubes of whole muscle grafts (both innervated and standard grafts, prior to the time of innervation) also develop presumptive secondary synaptic clefts and large, organized aggregations of AchRs at original synaptic sites. At later times, nerves regenerating into standard whole muscle and MEP-less grafts lead to the formation of numerous ectopic endplates. In whole muscle grafts, endplates may also form at original synaptic sites. Functional graft innervation is achieved in whole muscle and MEP-less grafts as early as 20 days postgrafting. The results of this study support the existence of still-unknown factors associated with the original synaptic site which can direct postsynaptic differentiation independent of innervation. They also demonstrate that functional endplates may form in mammalian muscle grafts at both original synaptic sites and ectopic locations, thus indicating that the zone of original synaptic sites is not necessary for the establishment of numerous functional and morphologically well-differentiated endplates.     

Immunohistochemical,Ultrastructural and Functional Analysis of Axonal Regeneration through Peripheral Nerve Grafts Containing Schwann Cells Expressing BDNF,CNTF or NT3

We used morphological, immunohistochemical and functional assessments to determine the impact of genetically-modified peripheral nerve (PN) grafts on axonal regeneration after injury. Grafts were assembled from acellular nerve sheaths repopulated ex vivo with Schwann cells (SCs) modified to express brain-derived neurotrophic factor (BDNF), a secretable form of ciliary neurotrophic factor (CNTF), or neurotrophin-3 (NT3). Grafts were used to repair unilateral 1 cm defects in rat peroneal nerves and 10 weeks later outcomes were compared to normal nerves and various controls: autografts, acellular grafts and grafts with unmodified SCs. The number of regenerated βIII-Tubulin positive axons was similar in all grafts with the exception of CNTF, which contained the fewest immunostained axons. There were significantly lower fiber counts in acellular, untransduced SC and NT3 groups using a PanNF antibody, suggesting a paucity of large caliber axons. In addition, NT3 grafts contained the greatest number of sensory fibres, identified with either IB₄ or CGRP markers. Examination of semi- and ultra-thin sections revealed heterogeneous graft morphologies, particularly in BDNF and NT3 grafts in which the fascicular organization was pronounced. Unmyelinated axons were loosely organized in numerous Remak bundles in NT3 grafts, while the BDNF graft group displayed the lowest ratio of umyelinated to myelinated axons. Gait analysis revealed that stance width was increased in rats with CNTF and NT3 grafts, and step length involving the injured left hindlimb was significantly greater in NT3 grafted rats, suggesting enhanced sensory sensitivity in these animals. In summary, the selective expression of BDNF, CNTF or NT3 by genetically modified SCs had differential effects on PN graft morphology, the number and type of regenerating axons, myelination, and locomotor function.     

The metabolism of skin grafts stored with excess carbon dioxide.

In Japan, the long-term storage of cereals and foods in the presence of excess carbon dioxide is already a practical reality. The present study was conducted to assess the metabolic changes in skin grafts during storage in the presence and absence of excess carbon dioxide, with the aim of seeking a simple and effective method to prolong skin-graft viability during storage. In experiment 1, 120 male Wistar rats weighing 250 to 300 gm were used. A split-thickness skin graft 450 microns in thickness was harvested from the back of each rat with a dermatome and was divided into two pieces for separate storage. One piece was stored in normal air at 4 degrees C (control grafts), and the other was stored in a gas mixture composed of 20% O2, 20% CO2, and 60% N2 at 4 degrees C (CO2 grafts). Metabolic changes in the skin grafts during storage were investigated by ATP and glucose assays. In experiment 2, 60 male Wistar rats were used. Collection and storage of the split-thickness skin grafts were performed as in experiment 1. In both groups, skin grafts were stored for 1, 2, or 3 weeks, and the oxygen consumption rate of each graft was determined. Experiment 3 used 80 male Wistar rats and the same procedure as in experiment 1; split-thickness skin grafts were harvested, divided into two pieces, and stored for 1, 2, or 3 weeks. In both groups, the stored skin grafts were regrafted onto the backs of the same donor rats.(ABSTRACT TRUNCATED AT 250 WORDS)     

The use of skin grafts in postburn contracture release: a 10-year review

Postburn scarring and contracture affecting function remain the most frustrating late complications of burn injury. Various techniques are used to release contractures; the choice depends on their location and/or the availability of unaffected skin adjacent to the contracture or elsewhere. A retrospective review was carried out of the case notes of patients who had skin grafting for the release of postburn contracture at the Burns Unit, City Hospital, Nottingham between May of 1984 and August of 1994 to evaluate the experience over this period. Information was obtained about the burn injury, contracture site, interval between burn and release of contracture, indication, age at first release, intervals between releases, operative details (donor and graft sites), complications and nonoperative treatment, and follow-up to the end of the study period. A total of 129 patients underwent skin grafting for release of contractures as opposed to any other method of correction. Full-thickness skin grafts were used in 81 patients (63 percent) and split-thickness skin grafts in 26 (20 percent). Twenty-two patients (17 percent) had both types used on different occasions. Flame burns (41 percent) were the most common causes, followed by scalds (38 percent). Two hundred thirty-nine sites of contracture were released, with the axilla (59) and the hand/wrist (59) being the most common sites involved, followed by the head/neck region (42). It was found that for the same site, release with split-thickness skin grafts was associated with more rereleases of the contracture than with full-thickness skin grafts. Also, the interval between the initial release and first rerelease was shorter than with full-thickness skin grafts (p < 0.048). It was also noted that children required more procedures during growth spurts, reflecting the differential effect of the growth of normal skin and contracture tissue. Patients reported more satisfaction with texture and color match with the full-thickness skin grafts. There was comparable donor-site and graft morbidity with both graft types. The use of skin grafts is simple, reliable, and safe. Whenever possible, the authors recommend the use of full-thickness skin grafts in preference to split-thickness skin grafts in postburn contracture release.     

Sensory restoration of the skin graft on a free muscle flap: experimental rabbit study.

Transplantation of a muscle flap with free skin graft for wound coverage is a common procedure in reconstructive microsurgery. However, the grafted skin has little or no sensation. Restoration of the sensibility of the grafted skin on the transferred muscle is critically important, especially in palmar hand, plantar foot, heel, and oral cavity reconstruction. The purpose of this study was to investigate the possibility of sensory restoration of the grafted skin on a trimmed muscle surface that has been sensory neurotized after sensory nerve-to-motor nerve transfer, using the rabbit gracilis muscle as an animal model. The ipsilateral saphenous nerve (sensory) was transferred to the motor nerve of the gracilis muscle for sensory neurotization. A 4 x 4-cm2 area of skin island over the midportion of the gracilis muscle was harvested as a full-thickness skin graft. The upper half of the gracilis muscle was then excised, becoming a rough surface. The harvested skin was reapplied on the trimmed rough surface of the muscle. After 6 months, retrograde and antegrade horseradish peroxidase labeling studies were performed through skin and muscle injection. The group with a free skin graft was compared with the group with an intact surface of the gracilis muscle. This study clearly shows that sensory nerves can regenerate and penetrate into the trimmed muscle surface and grow into the overlying grafted skin. However, if the muscle surface is intact as with the compared group, sensory reinnervation of the grafted skin is not possible.     

The role of grafted skin in the regeneration of X-irradiated axolotl limbs

The primary aim of these experiments was to follow the cells descended from limb skin through the process of limb regeneration to determine what range of differentiations these cells may assume. Triploid hindlimb or forelimb skin was grafted to the denuded thighs of diploid host axolotls that had previously received 3000 R of X irradiation across both hindlimbs and the intervening pelvic area. The host limbs were then amputated through their grafts and permitted to regenerate. Cartilage, perichondrium, joint connective tissue, general connective tissue, dermis, and epidermis were present in all the regenerated limbs, but only 10% of the regenerates contained muscle. Tabulation of nucleolar numbers showed that the majority of cells in each regenerated tissue originated from the grafted skin. A strong correlation was demonstrated between the forelimb or hindlimb origin of the skin grafts and the number of digits regenerated.     

Distinct in vivo CD8 and CD4 T cell responses against normal and malignant tissues

Normal tissue and tumour grafts expressing the same alloantigens often elicit distinct immune responses whereby only normal tissue is rejected. To investigate the mechanisms that underlie these distinct outcomes, we compared the responses of adoptively transferred HY-specific conventional (CD8 and CD4) or regulatory T (Treg) cells in mice bearing HY-expressing tumour, syngeneic male skin graft or both. For local T cell priming, T cell re-circulation, graft localization and retention, skin grafts were more efficient than tumours. Skin grafts were also capable of differentiating CD4 T cells into functional Th1 cells. Donor T cell responses were inversely correlated with tumour progression. When skin graft and tumour transplants were performed sequentially, contemporary graft and tumour burden enhanced CD8 but reduced CD4 T cell responses causing accelerated skin-graft rejection without influencing tumour growth. Although both skin grafts and tumours were able to expand HY-specific Treg cells in draining lymph node (dLN), the proportion of tumour-infiltrating Treg cells was significantly higher than that within skin grafts, correlating with accelerated tumour growth. Moreover, there was a higher level of HY antigen presentation by host APC in tumour-dLN than in graft-dLN. Finally, tumour tissues expressed a significant higher level of IDO, TGFβ, IL10 and Arginase I than skin grafts, indicating that malignant but not normal tissue represents a stronger immunosuppressive environment. These comparisons provide important insight into the in vivo mechanisms that conspire to compromise tumour-specific adaptive immunity and identify new targets for cancer immunotherapy.     

A nanofibrous PHBV tube with Schwann cell as artificial nerve graft contributing to Rat sciatic nerve regeneration across a 30-mm defect bridge

Abstract

A nanofibrous PHBV nerve conduit has been used to evaluate its efficiency based on the promotion of nerve regeneration in rats. The designed conduits were investigated by physical, mechanical and microscopic analyses. The conduits were implanted into a 30-mm gap in the sciatic nerves of the rats. Four months after surgery, the regenerated nerves were evaluated by macroscopic assessments and histology. This polymeric conduit had sufficiently high mechanical properties to serve as a nerve guide. The results demonstrated that in the nanofibrous graft with cells, the sciatic nerve trunk had been reconstructed with restoration of nerve continuity and formatted nerve fibers with myelination. For the grafts especially the nanofibrous conduits with cells, muscle cells of gastrocnemius on the operated side were uniform in their size and structures. This study proves the feasibility of artificial conduit with Schwann cells for nerve regeneration by bridging a longer defect in a rat model.     

Peptides and other neuronal markers in transplanted pancreatic islets

Functional alterations are developed in transplanted islets over time. Because islets in situ are densely innervated and isolation disconnects the endocrine organ from extrinsic nerves and from ganglia in the exocrine pancreas, it is important to examine the reinnervation of islet grafts. This review describes the patterns of appearances of intrinsic perikarya and reinnervating fibers demonstrating markers for parasympathetic, sympathetic or sensory nerve substances, most notably neuropeptides, in islet transplants. An altered innervation pattern, as compared to normal islets, develops. Presumably the expression of neuronal markers in the grafts is related to factors both in the islets and in the ectopic environment offered by the implantation organ.     

Survival of skin allografts following embryonic limb bud transplants in the turtle,Chelydra serpentina

Allografts of skin were observed in Chelydra serpentina. The response to these grafts was modified by a previous transplantation of a limb bud at an early embryonic stage. When the same donor was used for all transplants, the first skin graft was accepted by the host. A second skin graft, however, was rejected at about the rate of a simple first set allograft of skin. The animals were conditioned by the embryonic limb graft; this embryonic graft can be undergoing rejection at the same time a first set skin graft from the same donor was being accepted. The tolerance induced by the embryonic graft was sepcific for its donor.     

Prolonged life and improved quality for stored skin grafts

This study is presented as both a follow-up and an extension of previous work on storage techniques for the preservation of skin by refrigeration. Rabbit skin grafts were used to compare the merits of various storage media. One of the media, McCoy's 5A plus serum, gave improved skin graft take and storage half-life. The ability to improve skin graft storage techniques is most beneficial to all aspects of plastic and reconstructive surgery where skin grafting is required. Prolonged graft viability and improved graft quality are of major clinical importance.     

Effects on adult newt limb regeneration of partial and complete skin flaps over the amputation surface.

The influence of the wound epithelium on the cellular events preceding blastema formation was examined by comparing dedifferentiation, DNA labeling indices, and mitotic indices of the distal mesodermal tissues in control regenerating newt forelimbs and in amputated forelimbs covered with a flap of full thickness skin. Three kinds of results were seen following the skin-flap graft operations. Epidermal migration across the amputation surface was completely inhibited in 22% (8) of the cases and these limbs repaired the amputation wound but did not form regeneration blastemas. In 11% (4) of the experimental limbs, essentially normal wound epithelia displaced the skin flaps and the limb stumps formed blastemas and regenerated. The majority of the skin grafts (67%) exhibited epidermal migration restricted to the free edges of the flaps. These limbs formed eccentric blastemas on the ventral side of the limb next to the dermis-free epidermis and regenerated laterally in that direction.     

Neuromucosal prelaminated flaps for reconstruction of intraoral lining defects after radical tumor resection

To reconstruct intraoral lining defects after radical tumor resection by reinnervated vascularized mucosa, eight distal radial forearm flaps and two fibula flaps were prelaminated. Prelamination was performed by exposing the vascularized fascia, onto which the split distal end of a sural graft was fixed. The fascia and the sural nerve graft were covered by device-meshed mucosa or small full-thickness mucosa pieces. These structures again were covered by a Silastic sheet as large as the future flap, and the wound was closed by the elevated skin and subcutaneous tissue. Coverage by a Silastic sheet enabled mucosal spreading on the fascia, and the final flaps were thin, mucus-producing, and larger than the originally inserted mucosa. The 10 neuromucosal prelaminated flaps were harvested together with the inserted sural nerve graft after 8 to 10 weeks. During this time, the patient underwent radiotherapy and chemotherapy. Donor sites were closed directly by the preserved skin and subcutaneous tissue. Intraoral defects were reconstructed successfully by eight neuromucosal prelaminated distal radial forearm flaps and two neuromucosal prelaminated fibula flaps. The sural nerve grafts, inserted between the fascia and the mucosa, were coaptated eight times with the lingual nerve and two times with the inferior alveolar nerve. Intended reinnervation of the mucosa could already be proved clinically and histologically in the first two patients after 11 and 9 months. Preservation of skin and subcutaneous tissue considerably lowered donor-site morbidity. Neuromucosal prelamination enables reconstruction of intraoral lining defects by reinnervated mucus-producing tissue. Reconstruction of other mucosa-lined structures by this method seems feasible. Avoidance of skin islands for reconstruction lowers donor-site morbidity.