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Lateral Head (lateral + head)

Distribution by Scientific Domains
Medical Sciences50%

Selected Abstracts

Anatomic study and clinical application of distally-based neuro-myocutaneous compound flaps in the leg

MICROSURGERY, Issue 6 2007
Ai-Xi Yu M.D., Ph.D.
Objective: Anatomical study on the anastomosis between the neurovascular axis and the musculocutaneous perforators in leg. The distally-based neuron-myocutaneous flap was used for repairing special patients with soft tissue defect in foot and ankle. Methods: Systematical observation was carried out on 30 injected lower legs about the anastomosis between the neurovascular axis and the musculocutaneous perforators, and we summarized the clinical experiences from February 2004 on 12 cases using distally-based neuron-myocutaneous flap for repairing special patients with soft tissue defect in foot and ankle. Results: The neuron-vessels of sural nerve anastomosed permanently with the musculocutaneous perforators of medial and lateral head of gastrocnemius. There were two to three anastomoses found, respectively. The medial anastomotic branches were found larger in caliber than the lateral ones. The spatium intermuscular branches of the posterior tibial artery gave off their junior branches and anastomosed with the vessels in or out of the soleus muscle. There were two to three muscular branches perforated out of the soleus muscle, with mean caliber 0.5 ± 0.2 mm and accompanying with one to two veins. The neuron-vessels of the superficial fibular nerve gave off alone its course two to three muscular branches to the long extensor muscle digits and the long fibular muscle, and one to two fasciocutaneous to the skin. The diameter of the muscular branches was 0.4 ± 0.2 mm in average. Accounting for the operating models in the 12 cases, we had distally-based sural neuron-myocutaneous flap in 7 cases, saphenous neuron-myocutaneous flap in 4 cases, and superficial fibular neuron-myocutaneous flap in 1 case. All these cases were followed up at least for 2,6 months and had the significant results of nice limb's shape and cured osteomyelitis. Conclusion: Distally-based neuro-myocutaneous flap in leg can live with reliable blood circulation. These flaps offer excellent donor sites for repairing special the soft tissue defect in foot and ankle. © 2007 Wiley-Liss, Inc. Microsurgery, 2007. [source]

Muscle biopsy substantiates long-term MRI alterations one year after a single dose of botulinum toxin injected into the lateral gastrocnemius muscle of healthy volunteers,

MOVEMENT DISORDERS, Issue 10 2009
A. Sebastian Schroeder MD
Abstract Despite numerous clinical and experimental studies on botulinum toxin type A (BoNT/A), long-term alterations of muscle texture and fine structure following BoNT/A treatment have thus far not been studied in normal human skeletal muscle. After obtaining institutional review board approval, we performed a prospective, placebo-controlled, double-blinded follow-up study on two healthy adults using magnetic resonance imaging (MRI) and muscle biopsy to visualize long-term alterations after a single BoNT/A injection into the lateral head of the gastrocnemius muscle. MRI disclosed a high-signal-intensity pattern in short tau inversion recovery sequences, and a reduction of the cross-sectional area in the BoNT/A-injected, but not in the saline-injected contralateral control muscle (at 6 to 9 months in volunteer A: 73%, in B: 62%; at 12 months in A: 88%, and in B: 78%). Enzyme histochemistry, 12 months after injection, confirmed neurogenic atrophy of muscle fibers only in the BoNT/A-injected muscle. Electron microscopy revealed additional degenerative changes at the neuromuscular junction. The data confirm that MRI is a suitable tool to monitor the long-term effect of BoNT/A on skeletal muscle. Neurogenic muscle atrophy following a single BoNT/A injection should be taken into consideration when repeated BoNT/A injections into the same muscles are proposed. © 2009 Movement Disorder Society [source]

Anatomical variations of the plantaris muscle and a potential role in patellofemoral pain syndrome

CLINICAL ANATOMY, Issue 2 2008
A. Jay Freeman
Abstract The plantaris muscle has been given little attention in the reviewed literature. It is most commonly mentioned only when absent from a specimen. This study aimed to document the anatomy of the plantaris muscle and to discuss the clinical significance of the observations. Cadaveric knees (n = 46) were dissected to identify the possible variations of the plantaris muscle. The muscle conformed with standard descriptions (n = 26; 56.52%), was present but varied from previous descriptions (n = 14; 30.44%), or was absent (n = 6; 13.04%). The variations consisted of distinct interdigitations with the lateral head of the gastrocnemius muscle (n = 9; 19.57%) and a strong fibrous extension of the plantaris muscle to the patella (n = 5; 10.87%). The presence of interdigitations strengthen the argument that the plantaris muscle supplement the activity of the lateral head of the gastrocnemius muscle whereas the patellar extension suggests an involvement with patellofemoral dynamics and may play a role in the various presentations of patellofemoral pain syndrome. Greater understanding of the relationship between these and other posterior knee structures will facilitate more precise interpretation and treatment of knee injuries. Clin. Anat. 21:178,181, 2008. © 2008 Wiley-Liss, Inc. [source]

Restoration of motor function of the deep fibular (peroneal) nerve by direct nerve transfer of branches from the tibial nerve: An anatomical study,

CLINICAL ANATOMY, Issue 3 2004
Kale D. Bodily
Abstract Traction injuries of the common fibular (peroneal) nerve frequently result in significant morbidity due to tibialis anterior muscle paralysis and the associated loss of ankle dorsiflexion. Because current treatment options are often unsuccessful or unsatisfactory, other treatment approaches need to be explored. In this investigation, the anatomical feasibility of an alternative option, consisting of nerve transfer of motor branches from the tibial nerve to the deep fibular nerve, was studied. In ten cadaveric limbs, the branching pattern, length, and diameter of motor branches of the tibial nerve in the proximal leg were characterized; nerve transfer of each of these motor branches was then simulated to the proximal deep fibular nerve. A consistent, reproducible pattern of tibial nerve innervation was seen with minor variability. Branches to the flexor hallucis longus and flexor digitorum longus muscles were determined to be adequate, based on their branch point, branch pattern, and length, for direct nerve transfer in all specimens. Other branches, including those to the tibialis posterior, popliteus, gastrocnemius, and soleus muscles were not consistently adequate for direct nerve transfer for injuries extending to the bifurcation of the common fibular nerve or distal to it. For neuromas of the common fibular nerve that do not extend as far distally, branches to the soleus and lateral head of the gastrocnemius may be adequate for direct transfer if the intramuscular portions of these nerves are dissected. This study confirms the anatomical feasibility of direct nerve transfer using nerves to toe-flexor muscles as a treatment option to restore ankle dorsiflexion in cases of common fibular nerve injury. Clin. Anat. 17:201,205, 2004. © 2004 Wiley-Liss, Inc. [source]