Your search keyword '"Brushart TM"' showing total 6 results

1. Electrical Nerve Stimulation Enhances Perilesional Branching after Nerve Grafting but Fails to Increase Regeneration Speed in a Murine Model.

Author

Witzel C, Brushart TM, Koulaxouzidis G, and Infanger M

Subjects

Animals, Electrophysiology, Luminescent Proteins metabolism, Mice, Mice, Inbred C57BL, Sciatic Nerve physiology, Axons physiology, Electric Stimulation, Models, Animal, Nerve Regeneration physiology, Sciatic Nerve injuries, Sciatic Nerve transplantation, Synaptic Transmission physiology

Abstract

Background Electrical stimulation immediately following nerve lesion helps regenerating axons cross the subsequently grafted nerve repair site. However, the results and the mechanisms remain open to debate. Some findings show that stimulation after crush injury increases axonal crossing of the repair site without affecting regeneration speed. Others show that stimulation after transection and fibrin glue repair doubles regeneration distance. Methods Using a sciatic-nerve-transection-graft in vivo model, we investigated the morphological behavior of regenerating axons around the repair site after unilateral nerve stimulation (20 Hz, 1 hour). With mice expressing axonal fluorescent proteins (thy1-YFP), we were able to calculate the following at 5 and 7 days: percentage of regenerating axons and arborizing axons, branches per axon, and regeneration distance and speed. Results Brief stimulation significantly increases the percentage of regenerating axons (5 days: 35.5 vs. 27.3% nonstimulated, p < 0.05; 7 days: 43.3 vs. 33.9% nonstimulated, p < 0.05), mainly by increasing arborizing axons (5 days: 49.3 [4.4] vs. 33.9 [4.1]% [p < 0.001]; 7 days: 42.2 [5.6] vs. 33.2 [3.1]% [p < 0.001]). Neither branches per arborizing axon nor regeneration speed were affected. Conclusion Our morphological data analysis revealed that electrical stimulation in this model increases axonal crossing of the repair site and promotes homogeneous perilesional branching, but does not affect regeneration speed., (Thieme Medical Publishers 333 Seventh Avenue, New York, NY 10001, USA.)

Published

2016

2. Pathway sampling by regenerating peripheral axons.

Author

Witzel C, Rohde C, and Brushart TM

Subjects

Animals, Green Fluorescent Proteins metabolism, Mice, Mice, Transgenic, Neurites physiology, Sciatic Nerve cytology, Sciatic Nerve metabolism, Axons physiology, Motor Neurons physiology, Nerve Regeneration physiology, Neural Pathways physiology, Sciatic Nerve transplantation

Abstract

A century ago, Ramon y Cajal described the generalized response of regenerating peripheral axons to their environment. By using mice that express fluorescent proteins in their axons, we are now able to quantify the response of individual axons to nerve transection and repair. Sciatic nerves from nonexpressing mice were grafted into those expressing a yellow variant of green fluorescent protein, then examined at 5, 7, or 10 days after repair. Regeneration was found to be a staggered process, with only 25% of axons crossing the repair in the first week. In the setting of Wallerian degeneration, this stagger will expose growth cones to an evolving menu of molecular cues upon which to base pathway decisions. Many axons arborize, allowing them to interact simultaneously with several pathways. Arborization could serve as the anatomical substrate for specificity generation through collateral pruning. Axons often travel laterally across the face of the distal stump before choosing a pathway. As a result, the average unbranched axon has access to over 100 distal Schwann cell tubes. This extensive access, however, does not ensure correct matching of axon and end organ, suggesting that pathway choice is made on the basis of factors other than end organ identity. These observations explain the failure of refined surgical techniques to restore normal function after nerve injury. The apparent wandering of axons across the repair defies surgical control and mandates a biological approach to reuniting severed axons with appropriate distal pathways., (Copyright 2005 Wiley-Liss, Inc.)

Published

2005

3. Electrical stimulation promotes motoneuron regeneration without increasing its speed or conditioning the neuron.

Author

Brushart TM, Hoffman PN, Royall RM, Murinson BB, Witzel C, and Gordon T

Subjects

Animals, Axons physiology, Axotomy, Female, Ligation, Models, Animal, Nerve Crush, Rats, Rats, Sprague-Dawley, Time, Electric Stimulation Therapy methods, Femoral Nerve physiology, Motor Neurons physiology, Nerve Regeneration physiology, Sciatic Nerve physiology

Abstract

Motoneurons reinnervate the distal stump at variable rates after peripheral nerve transection and suture. In the rat femoral nerve model, reinnervation is already substantial 3 weeks after repair, but is not completed for an additional 7 weeks. However, this "staggered regeneration" can be temporally compressed by application of 20 Hz electrical stimulation to the nerve for 1 hr. The present experiments explore two possible mechanisms for this stimulation effect: (1) synchronization of distal stump reinnervation and (2) enhancement of regeneration speed. The first possibility was investigated by labeling all motoneurons that have crossed the repair at intervals from 4 d to 4 weeks after rat femoral nerve transection and suture. Although many axons did not cross until 3-4 weeks after routine repair, stimulation significantly increased the number crossing at 4 and 7 d, with only a few crossing after 2 weeks. Regeneration speed was studied by radioisotope labeling of transported proteins and by anterograde labeling of regenerating axons, and was not altered by stimulation. Attempts to condition the neuron by stimulating the femoral nerve 1 week before injury were also without effect. Electrical stimulation thus promotes the onset of motor axon regeneration without increasing its speed. This finding suggests a combined approach to improving the outcome of nerve repair, beginning with stimulation to recruit all motoneurons across the repair, followed by other treatments to speed and prolong axonal elongation.

Published

2002

4. The effects of free fat grafts on the stiffness of the rat sciatic nerve and perineural scar.

Author

Dumanian GA, McClinton MA, and Brushart TM

Subjects

Animals, Biomechanical Phenomena, Cicatrix etiology, Cicatrix pathology, Cicatrix physiopathology, Peripheral Nervous System Diseases etiology, Postoperative Complications pathology, Rats, Rats, Sprague-Dawley, Sciatic Nerve pathology, Sciatic Nerve physiopathology, Tissue Adhesions prevention & control, Adipose Tissue transplantation, Cicatrix prevention & control, Postoperative Complications prevention & control, Sciatic Nerve surgery

Abstract

We developed a new quantitative rat sciatic nerve model to test whether free fat grafts can reduce postoperative perineural scar formation. Epineurectomies of sciatic nerves were performed to create scar. The force required to distract the nerve a unit distance was measured after surgery to determine the time of maximal scar formation. Nerve stiffness normalized for rat weight was statistically greater at 2 months after the initial dissection (0.097+/-0.009 g/mm/g rat weight; n = 10 limbs) than rat limbs that had not undergone a previous dissection (0.075+/-0.012 g/mm/g rat weight). Perineural scar thickness was thicker at 2 months than the perineural tissue in preoperative controls. Free fat grafts decreased nerve stiffness at 2 months (0.078+/-0.012 g/mm/g rat weight) in comparison to the contralateral surgical control limb without a fat graft (0.094+/-0.014 g/mm/g rat weight). Free fat grafts reduced the strength of postoperative perineural scar in this surgical model; however, they were associated with an unexpected finding of substantial postoperative neuropathy.

Published

1999

5. Peripheral nerve repair with bioresorbable prosthesis.

Author

Nyilas E, Chiu TH, Sidman RL, Henry EW, Brushart TM, Dikkes P, and Madison R

Subjects

Animals, Mice, Mice, Inbred BALB C, Mice, Inbred C57BL, Polyesters, Prosthesis Design, Sciatic Nerve physiology, Biocompatible Materials, Prostheses and Implants, Sciatic Nerve surgery

Abstract

Using the transected sciatic nerve model in adult mice, regeneration of a large bundle of axons organized into the form of a nerve with myelinated and unmyelinated axons, Schwann cells, fibroblasts, collagen, blood vessels, and connective tissue sheaths has been achieved with bioresorbable microtubular guidance channels over gaps of 5 mm in nonimmobilized animals. After 4-6 wks postoperatively, the regenerated nerve cable contains on the order of 40% as many myelinated axons as were measured in the proximal nerve stumps. With the channels used so far in this model, regenerating axons pass into the distal stump in about 3-6 wks postoperatively. The guidance channels used consist of synthetic polyesters and/or polyester composites including glycolic and lactic acid polymers, and polyesters derived from Krebs Cycle dicarboxylic acids. Inflammatory response to these materials has been minimal. Biodegradation/resorption rates can be controlled so as to be compatible with axon growth rates.

Published

1983

6. Specificity of muscle reinnervation after epineurial and individual fascicular suture of the rat sciatic nerve.

Author

Brushart TM, Tarlov EC, and Mesulam MM

Subjects

Animals, Female, Motor Neurons physiology, Peroneal Nerve physiology, Rats, Rats, Inbred Strains, Sciatic Nerve physiology, Tibial Nerve physiology, Nerve Regeneration, Neuromuscular Junction physiology, Sciatic Nerve surgery, Suture Techniques

Abstract

We experimentally analyzed the specificity of muscle reinnervation after suture and regeneration of rat sciatic nerve. We used a horseradish peroxidase (HRP) technique of axon tracing to compare the number and location of motoneurons that innervate muscle via the peroneal nerve after epineurial and individual fascicular suture of the parent sciatic nerve. These motoneurons are significantly reduced in number from control levels and are often in spinal cord locations that indicate previous innervation of antagonistic muscle via the tibial nerve. This inappropriate reinnervation of peroneal muscle by tibial motoneurons is minimized by individual fascicular suture without compromise of overall reinnervation. Our findings thus support the hypothesis that individual fascicular suture may avoid distortion of the central connections of peripheral units.

Published

1983