Muscle Fiber Composition Changes after Selective Nerve Innervation.

Facial nerve paralysis interferes with mimetic muscle function. To reconstruct natural facial movement, free muscle flaps are transplanted as new muscles. However, it is difficult to maintain resting tonus. A dual innervation technique in which other nerves such as the hypoglossal nerve or contralateral facial nerve are added is often applied. Using 10-week-old rats (n = 10), the masseteric and hypoglossal nerves were cut, and the distal stump of the masseteric nerve and the proximal stump of the hypoglossal nerve were then sutured (suture group). In the other group, the masseteric nerve was cut and cauterized (cut group). Immunohistochemistry and microarray were performed on the extracted masseter muscle. The immunohistochemistry results suggested that the muscles in the suture group obtained oxidative characteristics. The microarray showed the genes involved in mitochondrial function, including Perm1. In summary, our data support the validity of the dualinnervation technique for facial paralysis treatment.

Efficacy of surgical repair for the functional restoration of injured facial nerve.

BACKGROUND: Early surgical repair to restore nerve integrity has become the most commonly practiced method for managing facial nerve injury. However, the evidence for the efficacy of surgical repair for restoring the function of facial nerves remains deficient. This study evaluated the outcomes of surgical repair for facial nerve lesions. METHODS: This retrospective observational study recruited 28 patients with the diagnosis of facial nerve injury who consecutively underwent surgical repairs from September 2012 to May 2019. All related clinical data were retrospectively analyzed according to age, sex, location of the facial nerve lesion, size of the facial nerve defect, method of repair, facial electromyogram, and blink reflex. Facial function was then stratified with the House-Brackmann grading system pre-operation and 3, 9, 15, and 21 months after surgical repair. RESULTS: The 28 patients enrolled in this study included 17 male and 11 female patients with an average age of 34.3 ± 17.4 years. Three methods were applied for the repair of an injured facial nerve, including great auricular nerve transplantation in 15 patients, sural nerve grafting in 7 patients, and hypoglossal to facial nerve anastomosis in 6 patients. Facial nerve function was significantly improved at 21 months after surgery compared with pre-operative function (P = 0.008). Following surgical repair, a correlation was found between the amplitude of motor unit potential (MUP) and facial nerve function (r = -6.078, P = 0.02). Moreover, the extent of functional restoration of the facial nerve at 21 months after surgery depended on the location of the facial nerve lesion; lesions at either the horizontal or vertical segment showed significant improvement(P = 0.008 and 0.005), while no functional restoration was found for lesions at the labyrinthine segment (P = 0.26). CONCLUSIONS: For surgical repair of facial nerve lesions, the sural nerve, great auricular nerve, and hypoglossal-facial nerve can be grafted effectively to store the function of a facial nerve, and MUP may provide an effective indicator for monitoring the recovery of the injured nerve.

Amer's classification of territories of facial nerve injury in early cases and strategies for the management of different territories.

Early cases of facial nerve injury are best treated by restoring the neural pathway to the same existing facial muscles. Knowledge of the exact territory of facial nerve injury is required to design a plane for the reconstruction of these injuries and to compare results. The current study aims to design a classification system for territories of facial nerve injury based on the location of nearest healthy fascicles to the site of injury both proximally and distally. Two hundred-one patients with early facial nerve injury were assessed for treatment. According to the results of the exploration, 13 territories of injury were identified. The management strategy was planned according to the territory of injury. The current classification system is a simple, easy and effective method for the classification of territories of facial nerve injury. The classification system accurately describes the nearest possible healthy proximal and distal fascicles and can be employed to easily report cases and implement a management plan. This classification scheme also allows us to more effectively compare results.

Facial reanimation: an update on nerve transfers in facial paralysis.

PURPOSE OF REVIEW: The aim of this article is to review the recent literature on nerve transfers in facial paralysis. The discussion focuses on direct nerve repair and three types of nerve transfers, cross facial nerve graft, hypoglossal, and masseter nerve transfers. RECENT FINDINGS: Masseteric nerve transfers have a high probability of creating significant movement, although tone is poor. The hypoglossal to facial nerve transfer is reliable in affording facial tone and has been updated to involve a transposition technique that offers good results with minimal morbidity. Combination nerve transfer techniques using multiple cranial nerves or cross-face nerves are increasingly described. SUMMARY: Reinnervation of the facial nerve and neural regeneration in general are areas of intense research and novel surgical approaches continue to be explored. Although direct nerve repair is the most ideal, other nerve transfers can be performed with good results. More specifically, the masseteric nerve transfer can provide excellent movement and the hypoglossal transfer good tone. Combination transfers may afford the benefits of multiple nerves.

Neurorrhaphy for Facial Reanimation with Interpositional Graft: Outcome in 23 Patients and the Impact of Timing on the Outcome.

OBJECTIVE: Neurorrhaphy with interpositional graft is a practical technique to achieve facial reanimation when the continuity of the facial nerve is interrupted and a large gap between the proximal and distal stump exists. The aim of this study was to report long-term outcomes of neurorrhaphy for facial reanimation with interpositional graft. The roles of some variable factors in the outcome of neurorrhaphy with interpositional graft were also evaluated and compared. METHODS: A retrospective case series from a single tertiary referral center comprised 23 patients with facial nerve interruptions who underwent neurorrhaphy with interpositional graft using either end-to-end anastomosis or end-to-side hypoglossal-facial technique. Preoperative data (age, sex, primary lesion, interval from paralysis to surgery, facial nerve function), intraoperative data (surgical approach, graft and type of neurorrhaphy), and postoperative data (facial nerve function) were collected and analyzed. RESULTS: Mean follow-up time was 26.6 ± 11.9 months. Patients who underwent neurorrhaphy for facial reanimation within 1 year after onset of facial paralysis were more likely to achieve House-Brackmann grade ≤3 compared with patients who underwent neurorrhaphy >1 year after onset of facial paralysis (odds ratio = 23.85, P = 0.04). No other factors were associated with improved outcomes. CONCLUSIONS: Early neurorrhaphy with interpositional graft (≤1 year) for facial reanimation resulted in better final facial nerve function outcomes compared with a delayed procedure.

The split hypoglossal nerve versus the cross-face nerve graft to supply the free functional muscle transfer for facial reanimation: A comparative study.

Long-standing cases of facial paralysis are currently treated with free functional muscle transfer. Several nerves are mentioned in the literature to supply the free muscle transfer. The aim of this study is to compare the split hypoglossal nerve and the cross-face nerve graft to supply the free functional muscle transfer in facial reanimation. Of 94 patients with long-standing, unilateral facial palsy, 49 were treated using the latissimus dorsi muscle supplied by the split hypoglossal nerve, and 45 patients were treated using the latissmus dorsi muscle supplied by healthy contralateral buccal branch of the facial nerve. The excursion gained by the free muscle transfer supplied by the split hypoglossal nerve (mean 19.20 ± 6.321) was significantly higher (P value 0.001) than that obtained by the contralateral buccal branch of the facial nerve (mean 14.59 ± 6.245). The split hypoglossal nerve appears to be a good possible option to supply the free vascularised muscle transfer in facial reanimation. It yields a stronger excursion in less time than the contralateral cross-face nerve graft.

Differential Reanimation of the Midface and Lower Face Using the Masseteric and Hypoglossal Nerves for Facial Paralysis.

BACKGROUND: Hypoglossal nerve transfer is frequently employed to reanimate the paralyzed facial muscles after irreversible proximal facial nerve injury. However, it can cause significant postoperative synkinesis because it involves the reinnervation of the whole mimetic musculature using a single motor source. OBJECTIVE: To describe our experience with differential reanimation of the midface and lower face using separate motor sources in patients with short-term facial paralysis after brain surgery. METHODS: Seven patients underwent combined nerve transfer (the masseteric nerve to the zygomatic branch and the hypoglossal nerve to the cervicofacial division of the facial nerve) and cross-facial nerve grafting with the aim of achieving a spontaneous smile. The median duration of paralysis before surgery was 7 mo and follow-up ranged from 7 to 31 mo (mean: 18 mo). For evaluation, both physical examination and video analysis were performed. RESULTS: In all patients, reanimation of both the midface and the lower face was successful. A nearly symmetrical resting lip was achieved in all patients, and they were able to voluntarily elevate the corners of their mouths without visible synkinesis and to close their eyes while biting. No patient experienced impairment of masticatory function or tongue atrophy. CONCLUSION: Differential reanimation of the midface and lower face with the masseteric and hypoglossal nerves is an alternative method that helps to minimize synkinetic mass movement and morbidity at the donor site.

A higher quality of life with cross-face-nerve-grafting as an adjunct to a hypoglossal-facial nerve jump graft in facial palsy treatment.

Nerve reconstructions are the preferred technique for short-standing facial paralysis, most commonly using the contralateral facial nerve or ipsilateral hypoglossal nerve. The hypoglossal nerve provides a strong motor signal, whereas the signal of a cross-face nerve graft is weaker but spontaneous. Spontaneity in facial expression is believed to be important for psychological wellbeing. Therefore, a combination of the two procedures incorporates the best of both: a strong motor signal and a spontaneous smile. This study aimed to objectify this expected benefit. Of the 20 patients who received a hypoglossal-facial nerve anastomosis from 1995 to 2015 in our institutions, 12 patients were included in this study, 5 with and 7 without a cross-face nerve graft. The outcomes were compared using photographs, disease-specific quality of life (Facial Clinimetric Evaluation (FaCE) scale), a self-reported synkinesis scale (Synkinesis Assessment Questionnaire) and the presence of a spontaneous smile. Significant differences were found in preoperative excursion of the affected side of the mouth and the change in excursion. Median Total FaCE scores were considerably larger (18.3 points) for patients who underwent the combined procedure. A spontaneous smile was observed both with (n = 2) and without (n = 1) a cross-face nerve graft. The addition of a cross-face nerve graft to a hypoglossal-facial nerve anastomosis resulted in a positive trend in disease-specific quality of life. This benefit could also be present with the combination of a cross-face nerve graft with another nerve transfer such as a masseteric-facial nerve anastomosis.

Masseteric to buccal branch nerve transfer.

PURPOSE OF REVIEW: To review recent literature pertaining to the use of masseteric-facial nerve neurorrhaphy (MFNN) for facial reanimation in patients with facial paralysis. RECENT FINDINGS: First, MFNN effectively restores some midface tone and function, including the ability to smile. Second, use of the masseteric nerve minimizes synkinesis, dysarthria, and dysphagia that frequently occur after hypoglossal-facial nerve neurorrhaphy. Third, concurrent cable grafting to the zygomatic branch from an intact proximal facial nerve remnant - when available - can restore dynamic eye closure. SUMMARY: Masseteric nerve transfer is an alternative to hypoglossal nerve transfer that improves midface appearance and function for properly selected patients with facial paralysis.

Facial nerve repair after operative injury: Impact of timing on hypoglossal-facial nerve graft outcomes.

PURPOSE: Reanimation of facial paralysis is a complex problem with multiple treatment options. One option is hypoglossal-facial nerve grafting, which can be performed in the immediate postoperative period after nerve transection, or in a delayed setting after skull base surgery when the nerve is anatomically intact but function is poor. The purpose of this study is to investigate the effect of timing of hypoglossal-facial grafting on functional outcome. MATERIALS AND METHODS: A retrospective case series from a single tertiary otologic referral center was performed identifying 60 patients with facial nerve injury following cerebellopontine angle tumor extirpation. Patients underwent hypoglossal-facial nerve anastomosis following facial nerve injury. Facial nerve function was measured using the House-Brackmann facial nerve grading system at a median follow-up interval of 18months. Multivariate logistic regression analysis was used determine how time to hypoglossal-facial nerve grafting affected odds of achieving House-Brackmann grade of ≤3. RESULTS: Patients who underwent acute hypoglossal-facial anastomotic repair (0-14days from injury) were more likely to achieve House-Brackmann grade ≤3 compared to those that had delayed repair (OR 4.97, 95% CI 1.5-16.9, p=0.01). CONCLUSIONS: Early hypoglossal-facial anastomotic repair after acute facial nerve injury is associated with better long-term facial function outcomes and should be considered in the management algorithm.

Laryngeal Reinnervation Using a Split-Hypoglossal Nerve Graft in a Canine Model.

IMPORTANCE: Vocal fold immobility following injury to the recurrent laryngeal nerve (RLN) may lead to substantial morbidity. A reinnervation treatment strategy offers several theoretical benefits over static treatment options. This study evaluates the robustness of reinnervation of the larynx using a split-hypoglossal nerve graft in an animal model, with outcomes assessed by independent blinded review. OBJECTIVES: To assess whether a full-hypoglossal nerve graft to the RLN after RLN section can provide return of dynamic vocal fold motion in a canine model, and to validate that a split-hypoglossal nerve graft to the RLN may also provide dynamic vocal fold motion to rehabilitate laryngeal function in a canine model. DESIGN, SETTING, AND SUBJECTS: A pilot animal study to assess the feasibility and morbidity of laryngeal reinnervation following RLN injury with an end-to-end full-hypoglossal or split-hypoglossal nerve graft was performed at an animal care and research facility in 10 adult female dogs. The study dates were January to July 2013. INTERVENTIONS: We performed full-hypoglossal (full XII group [n = 5]) and split-hypoglossal (split XII group [n = 5]) nerve grafts to the RLN in a canine model following RLN section. MAIN OUTCOMES AND MEASURES: Morbidity was evaluated through scored feeding observation. Laryngeal function was assessed by video laryngoscopy and evoked laryngeal electromyography was performed at baseline and 6 months after surgery. Video laryngoscopy was graded by independent reviewers blinded to study intervention. RESULTS: No clinically significant morbidity was identified after surgery. On review of video laryngoscopy, all 5 animals in the full XII group and all 5 animals in the split XII group demonstrated vocal fold motion by at least 1 independent reviewer. All 3 reviewers agreed on motion in 1 of 5 animals in the full XII group and in 1 of 5 animals in the split XII group. Stimulation of the hypoglossal nerve demonstrated neural connection on evoked laryngeal electromyography in all animals at 6 months. CONCLUSIONS AND RELEVANCE: This study confirms that a full-hypoglossal or split-hypoglossal nerve graft may restore vocal fold motion, without significant functional morbidity, following RLN section in a canine model.

Hemi-hypoglossal nerve transfer for obstetric brachial plexus palsy: report of 3 cases.

Use of the entire hypoglossal nerve for nerve transfer in obstetric palsy is not recommended because of major donor nerve morbidity in terms of feeding and speech problems. We used a hemi-hypoglossal nerve transfer for biceps reinnervation in obstetric palsy in 3 infants with multiple root avulsions. Two of the 3 infants recovered normal or near-normal elbow flexion. There was no donor nerve morbidity in terms of feeding. Speech was assessed at age 20 to 27 months and was appropriate for age, which indicates that early speech development (speech intelligibility and articulation) were not affected. However, phonological development (expected to develop by age 3 y) and full consonant development (expected to be complete by age 5 y) could not be assessed because all children were younger than age 3 years at final follow-up. Our results confirm the relative safety of using a hemi-hypoglossal nerve transfer in infants. The transfer deserves study in a larger series and with longer follow-up, particularly regarding speech development.

Comparison of hemihypoglossal nerve versus masseteric nerve transpositions in the rehabilitation of short-term facial paralysis using the Facial Clima evaluating system.

BACKGROUND: Masseteric and hypoglossal nerve transfers are reliable alternatives for reanimating short-term facial paralysis. To date, few studies exist in the literature comparing these techniques. This work presents a quantitative comparison of masseter-facial transposition versus hemihypoglossal facial transposition with a nerve graft using the Facial Clima system. METHODS: Forty-six patients with complete unilateral facial paralysis underwent reanimation with either hemihypoglossal transposition with a nerve graft (group I, n = 25) or direct masseteric-facial coaptation (group II, n = 21). Commissural displacement and commissural contraction velocity were measured using the Facial Clima system. Postoperative intragroup commissural displacement and commissural contraction velocity means of the reanimated versus the normal side were first compared using a paired sample t test. Then, mean percentages of recovery of both parameters were compared between the groups using an independent sample t test. Onset of movement was also compared between the groups. RESULTS: Significant differences of mean commissural displacement and commissural contraction velocity between the reanimated side and the normal side were observed in group I but not in group II. Mean percentage of recovery of both parameters did not differ between the groups. Patients in group II showed a significantly faster onset of movement compared with those in group I (62 ± 4.6 days versus 136 ± 7.4 days, p = 0.013). CONCLUSIONS: Reanimation of short-term facial paralysis can be satisfactorily addressed by means of either hemihypoglossal transposition with a nerve graft or direct masseteric-facial coaptation. However, with the latter, better symmetry and a faster onset of movement are observed. In addition, masseteric nerve transfer avoids morbidity from nerve graft harvesting. CLINICAL QUESTION/LEVEL OF EVIDENCE: Therapeutic, III.

[In vivo study on tissue engineered skeletal muscle with hypoglossal nerve implantation].

OBJECTIVE: To construct tissue engineered skeletal muscle in vivo using glial cell derived neurotrophic factor (GDNF) genetically modified myoblast (Mb) on acellular collagen sponge with hypoglossal nerve implantation, and to observe whether structural or functional connection could be established between engineered tissue and motor nerve or not. METHODS: Mbs were isolated from 7 male Lewis rats at age of 2 days, cultured and genetically modified by recombinant adenovirus carrying GDNF cDNA (Mb(GDNF)). Calf skin-derived acellular collagen sponge was used as scaffold; cell adhesion was detected by scanning electron microscope after 24 hours. Hypoglossal nerve was implanted into Mb-scaffold complex (Mb group, n = 27) or Mb(GDNF)-scaffold complex (Mb(GDNF) group, n = 27) in 54 female Lewis rats at age of 8 weeks. HE staining was performed at 1, 6, and 12 weeks postoperatively, and immunohistochemistry staining and fluorescence in situ hybridization were used. RESULTS: Mb(GDNF) could highly expressed GDNF gene. Mb and Mb(GDNF) could adhere to the scaffold and grew well. HE staining showed tight junctions between implant and peripheral tissue with new muscle fiber and no distinguished line at 12 weeks in 2 groups. Immunohistochemistry staining showed that positive cells of myogenin and slow skeletal myosin were detected, as well as positive cells of acetylcholine receptor alpha1 at 1, 6, and 12 weeks. The positive cells of Y chromosome decreased with time. At 1, 6, and 12 weeks, the positive neurons were 261.0 +/- 6.6, 227.3 +/- 8.5, and 173.3 +/- 9.1, respectively in Mb(GDNF) group, and were 234.7 +/- 5.5, 196.0 +/- 13.5, and 166.7 +/- 11.7, respectively in Mb group; significant differences were found between 2 groups at 1 and 6 weeks (P < 0.05), no significant difference at 12 weeks (P > 0.05). CONCLUSION: Connection can be established between engineered tissue and implanted hypoglossal nerve. Recombinant GDNF produced by Mb(GDNF) might play a critical role in protecting central motor neurons from apoptosis by means of retrograde transportation.

Comparison of hemihypoglossal-facial nerve transposition with a cross-facial nerve graft and muscle transplant for the rehabilitation of facial paralysis using the facial clima method.

To compare quantitatively the results obtained after hemihypoglossal nerve transposition and microvascular gracilis transfer associated with a cross facial nerve graft (CFNG) for reanimation of a paralysed face, 66 patients underwent hemihypoglossal transposition (n = 25) or microvascular gracilis transfer and CFNG (n = 41). The commissural displacement (CD) and commissural contraction velocity (CCV) in the two groups were compared using the system known as Facial clima. There was no inter-group variability between the groups (p > 0.10) in either variable. However, intra-group variability was detected between the affected and healthy side in the transposition group (p = 0.036 and p = 0.017, respectively). The transfer group had greater symmetry in displacement of the commissure (CD) and commissural contraction velocity (CCV) than the transposition group and patients were more satisfied. However, the transposition group had correct symmetry at rest but more asymmetry of CCV and CD when smiling.

Split hypoglossal-facial nerve neurorrhaphy for treatment of the paralyzed face.

BACKGROUND: Several methods of neural rehabilitation for facial paralysis using 12-7 transfers have been described. The purpose of this study is to report on a series for dynamic reinnervation of the paralyzed face by using a split 12-7 nerve transposition. The goals of this procedure are to minimize tongue morbidity and to provide good facial reinnervation. METHODS: Prospective case series. Melolabial crease discursion, overall facial movement, and degree of tongue atrophy and mobility were recorded. RESULTS: Thirteen patients underwent facial reanimation using a split hypoglossal-facial nerve transfer with postoperative follow-up to 58 months (range, 6-58 months). All patients achieved excellent rest symmetry and facial tone. Of 13 patients, 10 had measurable coordinated movement and discursion of their melolabial crease. Of 13 patients, 12 had mild to moderate ipsilateral tongue atrophy. The mean time to onset of visible reinnervation was 3 months. CONCLUSION: Split hypoglossal-facial nerve transposition provides good rehabilitation of facial nerve paralysis with reduced lingual morbidity. Long-term rest symmetry and potential learned movement can be achieved. This technique may provide a favorable alternative to the traditional method of complete hypoglossal sacrifice or jump grafting.

A single hypoglossal nerve for bilateral smile reconstruction in Möbius syndrome.

Möbius syndrome is a rare congenital disorder characterized by a variety of cranial nerve defects. Although there are several variants of Möbius syndrome depending on which cranial nerves are affected, the commonest form involves facial and abducens cranial nerve paralysis. Despite several strategies for bilateral smile reconstruction that have been advocated, the condition still presents a challenge to the plastic surgeon. The most acceptable method nowadays is bilateral free neurovascularized muscle transfer. The author represents a new method of using a single hypoglossal nerve to supply both free flaps in a Möbius patient. The procedure is done on 2 stages using both latissimus dorsi muscles and a single hypoglossal nerve. The patient regained a natural symmetric smile 12 months after the first stage. Despite hemilingual atrophy, no tongue morbidity was observed. The author concludes that despite the limitation of the study, the hypoglossal nerve is a good nerve source to supply both free flaps for smile reconstruction in Möbius syndrome.

Outcomes of mini-hypoglossal nerve transfer and direct muscle neurotization for restoration of lower lip function in facial palsy.

BACKGROUND: Most reconstructions for lower lip palsy focus on paralyzing the contralateral normal lip or providing static support on the affected side. The authors' unit has reported dynamic strategies for lower lip reanimation and use of 40 percent of the hypoglossal nerve (mini-hypoglossal) in facial reanimation. They report their experience with mini-hypoglossal nerve transfer for lower lip palsy. METHODS: Between 1987 and 2005, 29 patients with unilateral facial palsy had lower lip reanimation with the mini-hypoglossal as the motor donor. Twenty patients had transfer of the mini-hypoglossal to the cervicofacial branch of the facial nerve and nine had direct depressor muscle neurotization. Five patients had a mean denervation time of 14.60 +/- 4.50 months (<2 years), and the rest had a mean denervation time of 10.63 +/- 9.23 years. In late cases, the facial nerve was in-continuity, and preoperative needle electromyographs of depressors showed at least fibrillations. Standardized videos taken preoperatively and at 2 years postoperatively were available for 27 patients and assessed by three independent reviewers. Needle electromyographic results were analyzed. RESULTS: Thirteen patients (48.15 percent) achieved excellent and good results, nine (33.33 percent) had moderate results, and five (18.52 percent) obtained fair results. The difference between the averaged preoperative and postoperative scores was statistically significant, as was the difference in electromyographic outcomes (p < 0.0001, Wilcoxon signed rank test). The nerve transfer and direct neurotization groups had no statistically significant difference in clinical and electromyographic outcomes. Four patients required muscle transfer for further outcome upgrading. CONCLUSION: Use of the mini-hypoglossal either for nerve transfer or for direct muscle neurotization of lower lip depressors can provide reinnervation and satisfactory clinical function, even for muscles with prolonged partial denervation.

Neurovascular anatomy of sartorius muscle flaps: implications for local transposition and facial reanimation.

BACKGROUND: The sartorius muscle is a superficial muscle of the thigh that possesses highly suitable qualities for many uses in local transposition and free muscle transfer. However, a paucity of description of the neurovascular anatomy of the sartorius has contributed to its infrequent use in these roles. METHODS: Both human and canine studies were undertaken to delineate the neurovascular anatomy of the sartorius and to determine the role for surgical delay clinically. Fifty-five human cadaveric sartorius muscles and 30 canine cadaveric sartorius muscles underwent angiographic and dissection studies, and the location and course of the vessels and nerves supplying sartorius are described. A subsequent study was undertaken in two live canines in which the vascular supply to the sartorius was evaluated before and after surgical delay. RESULTS: The sartorius is supplied by an average of six or seven vascular pedicles, the size, location, and course of which are described. The nerve supply to the sartorius enters at its proximal end and uniformly arises from a branch of the femoral nerve. Variations in branching patterns and course of nerves and vessels are described. Living canine studies demonstrated the dilatation of intramuscular vessels following surgical delay, with the contrast injection of a single remaining vascular pedicle shown to vascularize the entire length of the sartorius muscle. CONCLUSIONS: The sartorius is highly suitable for local transposition and free muscle transfer for facial reanimation. The neurovascular anatomy is reliable, and the use of surgical delay can augment its vascular supply and increase the arc of rotation for local transposition.

Our experience with surgical treatment of lesions of nervus facialis.

OBJECTIVE: The study presents the results of reconstruction surgery of lesions on n. facialis with n. hypoglossus and n. accessorius performed in our clinic. PATIENT GROUP AND METHODS: 10 patients were treated by anastomosis of n. facialis with n. hypoglossus (HFA), 1 patient by anastomosis of n. facialis with n. accessorius (AFA). All operations were performed under the microscope; HFA and AFA anastomoses were sewed without tension at perineurium. The techique of suturation of facial nerves did not differ from the suturation of peripheral nerves in extremities. For the connection of n. VII-XII was not used plasma pasting. We did not use end to side anastomosis or reconstruction of n. VIIVII in pontocerebellar angle, in pyramid, or symetrical anastomoses of n. VII-VII, in any case. The results were objectivized by a VI grade Brudny's modification of House-Brackman classification introduced originally for scaling of the outcome of HFA anastomosis. In this study, this classification has been used for the objectivization of AFA anastomosis results. RESULTS: Reconstruction surgery by HFA and AFA resulted in all cases in grade III of the scale. Glossal hemiatrophy or atrophy of m. sternocleidomastoideus and m. trapesius were observed in patients treated by cross anastomosis with n. hypoglossus or n. accessorius. In patients treated by HFA and even more pronounced in patient with AFA anastomosis, minute synkineses in the region of labial angle, chin, also in the region of lower eyelid, occurred in the excited emotional state or during a long-lasting speech. Major diskincses were not observed in any of reported treatments. Recovery in older patients up to 60 years was coming more slowly, in one case after 6 months. CONCLUSION: Compared to AFA anastomosis, HFA anastomoses resulted in improved mimics and synkineses present here were finer. We prefer HFA anastomosis also because the discomfort caused by atrophy of ni. trapesius and ni. sternocleidomastoideus was apparently more perceived by patient treated by AFA than the negative effects of hemiatrophy reported by patients treated by FIFA.