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Clinical Trial Details — Status: Not yet recruiting

Administrative data

NCT number NCT04543318
Other study ID # NCT04543318
Secondary ID
Status Not yet recruiting
Phase N/A
First received
Last updated
Start date November 1, 2020
Est. completion date April 1, 2023

Study information

Verified date September 2020
Source Assiut University
Contact Ahmed Abdelkarim, MD
Phone 00201008022747
Email ahmed.abdelkarim@med.aun.edu.eg
Is FDA regulated No
Health authority
Study type Interventional

Clinical Trial Summary

The return of eyelid function and facial expression in Patients with facial nerve affection is very important for quality of life. Eyelid dysfunction leads to drying and ulceration of cornea which may lead to permanent vision loss.

Facial paralysis is distinguished into two main groups according to the presence or absence of facial fibrillations at needle Electromyography. Recent paralysis, mainly lasting less than two years generally show these signs and are eligible for reactivation of facial nerve by anastomosing it to a donor one (early facial reanimation).

The masseteric nerve (motor branch of trigeminal nerve ) is a reliable donor nerve on early facial reanimation.

The deep temporal nerves are motor branches of trigeminal nerve which have some advantage over masseteric nerve as they are longer and reach the zygomatic and frontal branch of facial nerve and it can reach the eyelid and eyebrow to be used for direct neurotization and it supplies temporalis muscle which is an expandable muscle with little effect on mastication and it was reported that they can restore blinking.

So on this study we examine the advantages and disadvantages of both nerves to develop a protocol for use of both especially on eyelid reanimation and restoration of blinking on upper facial segment paresis


Description:

Type of the study: Prospective Interventional Study (clinical trial)

Intervention Model Description:

Patients will be randomized into two groups according to the surgical procedure performed as follows:

- Group A: Deep temporal nerves.

- Group B: Masseteric nerve.

Allocation and Randomization:

Twenty-four patients will be randomly assigned to Group A or Group B (2 equal groups).

Simple randomization will be performed before surgery by a research nurse using the closed-envelope technique.

Twenty-four closed envelopes will be used, each 12 of them carries one of the 2 groups. Closed envelope will be randomly withdrawn the night before surgery to assign the patient to his specific group.

Study Setting: Plastic and Reconstructive Surgery Department, Assuit University Hospital

Study subjects:

Inclusion criteria:

1. Facial nerve paresis with upper eyelid affection.

2. Patients are generally fit with no other disease interfere with microsurgery.

3. Electromyography of eyelid showing fibrillations. b. Exclusion criteria:

1. Patient with other medical or mental disease causing generalized paralysis. 2. Syndromic cases. 3. Patients are generally unfit or with any disease interfere with microsurgery.

4. Electromyography of eyelid showing no fibrillations.

Sample Size Calculation: 24 Sample size was calculated using G power program version 3.1.9.4 (6) in order to detect a significant difference in mean of palpebral fissure height (one of main assessed outcomes in the study ) between two groups under the study , assumed effect size 0.6 based on clinical assumption ( novel study ), α error 0.3 , power 0.80, and allocation ratio 1: 1.

Twenty-two patient plus 10% for dropouts to make total twenty-four (12 patient for every group).

Study tools

All patients in this study are subjected to:

Pre-operative Assessment:

1. Patient history.

2. All patients will do preoperative clinical and neurophysiological assessments of mimetic muscle function and donor nerve status (the ipsilateral deep temporal nerve. The neurophysiological tests will include needle Electromyography (EMG) for recruitment of residual motor unit action potential. If there are no fibrillations patients will have another surgical procedure.

3. The trigeminal motor component will be tested by palpating the temporalis muscle during chewing and via needle EMG of the temporalis muscle to verify availability as a donor motor nerve.

4. Photographic documentation preoperative using standardized frontal face view and adding a scale to photo to measure the palpebral fissure size during three states normal eye opening, resting eye closure and forced eye closure using ImageJ (image processing and analysis in java) computer software (7).

5. Ophthalmological assessment of the affected eye for detection of redness, ulcer, etc.

Surgical procedure:

Group A We will avoid the use of muscle relaxants to induce anaesthesia and employ an electro-stimulator to identify the deep temporal nerves and the facial nerve branches supplying the eyelid on the affected side.

Exploration on the affected side a facelift-type incision will be performed, and an anterior subcutaneous flap is then will be lifted for several centimetres. In the inferior zygomatic region, the plane of elevation is deepened into the sub-SMAS plane and a composite flap elevated for several centimetres. Following elevation in this plane, the distal facial nerve branches will be identified. The distal portion of the zygomatic nerve is usually located midway between the oral commissure and the helical root. and was confirmed by nerve stimulator.

The deep temporal fascia and temporalis muscle will be incised along the temporal fusion line and will be reflected from the skull to expose the divisions of the deep temporal nerves and the longest branch was traced and prepared for anastomosis end to end with the zygomatic branch after confirming the eyelid supply(8).

Then suction drain will be put and will be removed after 24 hours. Group B The same procedure except tracing the masseteric nerve related to masseter muscle and anastomosis will be the same (9).

Post-operative All patient will receive physiotherapy and post-operative follow up to detect any wound complication.

Evaluation (After 6 months from the operation)

1. Photo documentation: measurement of the palpebral fissure size during three states normal eye opening, resting eye closure , forced eye closure will be done adding eye closure during mastication to compare with preoperative resting eye closure measure using ImageJ (image processing and analysis in java) computer software(7).

2. Donor site morbidity.

3. Follow up Ophthalmological assessment.

Complications:

1. General surgical complication.

2. General complication due to general anaesthesia.

3. Specific complication:

1. Delayed healing of nerve anastomosis.

2. Affection of mastication.

3. No postoperative improvement.

Research outcome measures:

a. Primary (main): Comparing the outcomes on palpebral fissure size between the deep temporal group and the masseteric group after 6 months from the surgery.

a. Secondary (subsidiary):

1. Procedure-related morbidity and mortality.

2. Operative time and hospital stay.


Recruitment information / eligibility

Status Not yet recruiting
Enrollment 24
Est. completion date April 1, 2023
Est. primary completion date December 1, 2022
Accepts healthy volunteers No
Gender All
Age group N/A and older
Eligibility Inclusion Criteria:

1. Facial nerve paresis with upper eyelid affection.

2. Patients are generally fit with no other disease interfere with microsurgery. 3.Electromyography of eyelid showing fibrillations.

Exclusion Criteria:

1. Patient with other medical or mental disease causing generalized paralysis.

2. Syndromic cases.

3. Patients are generally unfit or with any disease interfere with microsurgery.

4. Electromyography of eyelid showing no fibrillations.

Study Design


Related Conditions & MeSH terms


Intervention

Procedure:
Deep temporal nerves
Surgical procedure: Group A Exploration on the affected side a facelift-type incision will be performed, and an anterior subcutaneous flap is then will be lifted for several centimetres. In the inferior zygomatic region, the plane of elevation is deepened into the sub-SMAS plane and a composite flap elevated for several centimetres. Following elevation in this plane, the distal facial nerve branches will be identified. The distal portion of the zygomatic nerve is usually located midway between the oral commissure and the helical root. and was confirmed by nerve stimulator. The deep temporal fascia and temporalis muscle will be incised along the temporal fusion line and will be reflected from the skull to expose the divisions of the deep temporal nerves and the longest branch was traced and prepared for anastomosis end to end with the zygomatic branch after confirming the eyelid supply.
massteric nerve
group B The same procedure as group A except tracing the masseteric nerve related to masseter muscle and anastomosis will be the same

Locations

Country Name City State
n/a

Sponsors (1)

Lead Sponsor Collaborator
Assiut University

References & Publications (9)

Biglioli F, Frigerio A, Colombo V, Colletti G, Rabbiosi D, Mortini P, Dalla Toffola E, Lozza A, Brusati R. Masseteric-facial nerve anastomosis for early facial reanimation. J Craniomaxillofac Surg. 2012 Feb;40(2):149-55. doi: 10.1016/j.jcms.2011.03.005. Epub 2011 Apr 3. — View Citation

Dauwe PB, Hembd A, De La Concha-Blankenagel E, Saba S, White C, Cardenas-Mejia A, Rozen SM. The Deep Temporal Nerve Transfer: An Anatomical Feasibility Study and Implications for Upper Facial Reanimation. Plast Reconstr Surg. 2016 Sep;138(3):498e-505e. doi: 10.1097/PRS.0000000000002482. — View Citation

Faul F, Erdfelder E, Lang AG, Buchner A. G*Power 3: a flexible statistical power analysis program for the social, behavioral, and biomedical sciences. Behav Res Methods. 2007 May;39(2):175-91. — View Citation

Gray ML, Hu S, Gorbea E, Mashkevich G. Masseteric-zygomatic nerve transfer for the management of eye closure-smile excursion synkinesis. Am J Otolaryngol. 2020 Jul - Aug;41(4):102479. doi: 10.1016/j.amjoto.2020.102479. Epub 2020 Apr 4. — View Citation

Karagoz H, Ozturk S, Malkoc I, Diyarbakir S, Demirkan F. Anatomy of the Anterior Deep Temporal Nerve: Implications for Neurotization in Blinking Restoration in Facial Paralysis. Ann Plast Surg. 2015 Sep;75(3):316-8. doi: 10.1097/SAP.0000000000000552. — View Citation

Okochi M, Okochi H, Asai E, Sakaba T, Ueda K. Eyelid reanimation using crossface nerve graft: Relationship between surgical outcome and preoperative paralysis duration. Microsurgery. 2018 May;38(4):375-380. doi: 10.1002/micr.30264. Epub 2017 Nov 10. — View Citation

Okochi M, Ueda K, Okochi H, Asai E, Sakaba T, Kajikawa A. Facial reanimation using hypoglossal-facial neurorrhaphy with end-to-side coaptation between the jump interpositional nerve graft and hypoglossal nerve: Outcome and duration of preoperative paralysis. Microsurgery. 2016 Sep;36(6):460-6. doi: 10.1002/micr.22393. Epub 2015 Aug 28. — View Citation

Schneider CA, Rasband WS, Eliceiri KW. NIH Image to ImageJ: 25 years of image analysis. Nat Methods. 2012 Jul;9(7):671-5. — View Citation

Terzis JK, Tzafetta K. The "babysitter" procedure: minihypoglossal to facial nerve transfer and cross-facial nerve grafting. Plast Reconstr Surg. 2009 Mar;123(3):865-76. doi: 10.1097/PRS.0b013e31819ba4bb. — View Citation

Outcome

Type Measure Description Time frame Safety issue
Primary Palpebral fissure size Comparing the outcomes on palpebral fissure size between the deep temporal group and the masseteric group after 6 months from the surgery. 6 months after surgery
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