LATERAL SUPRAMALLEOLAR FLAP IN RECONSTRUCTION OF PRESSURE ULCERS IN PATIENTS WITH SPINAL CORD INJURY

Foot and ankle reconstruction using the lateral supramalleolar flap versus the anterolateral thigh flap in the elderly: A comparative study

The purpose of this study was to compare the reconstructive outcomes of soft‐tissue defects around the foot and ankle with anterolateral thigh (ALT) flap or lateral supramalleolar (LSM) flap and attempt to provide an optimal strategy for elderly patients. A retrospective review of all continuous patients with foot and ankle reconstruction using different flaps from October of 2010 and October of 2020 was performed. Based on the flap types, the patients were divided into two groups: ALT flap group (n = 50) and LSM flap group (n = 46). Outcomes were assessed according to the flap survival rate, early complications, general complications, late complications, cosmetic appearance, functional outcomes and Vancouver Scar Scale (VSS). We found that there was no difference in average age, gender, aetiology, size of the defect, debridement times between the two groups; however, a significant difference in operation time, hospitalisation time and cost were noted between them. What's more, the early flap complications between them were not significantly different. The LSM flap group showed less general complications, less flap bulky and lower cosmetic appearance. Moreover, the functional evaluation and VSS seem similar (P > .05). Thus, The ALT flap and LSM flap are both flaps available for foot and ankle reconstruction in elderly patients. However, the LSM flap offers short operation time, short hospitalisation time, and less cost with a lower frequency of postoperative complications. Thus, we advocate the LSM flap for the reconstruction of moderate‐size defects of the foot and ankle region in elderly patients.

Lower limb perforator flaps: Current concept

Following a long period dominated by random fasciocutaneous flaps or muscle flaps, solutions to cover the lower limb have been largely diversified by the advent of so-called "perforator" flaps. Extended knowledge of vascular anatomy has propagated the development of this innovative procedure, in the objective of reducing morbidity. The existence of close to 400 perforator vessels in the body makes it possible to offer new flap perspectives for many defects, which were sometimes previously impossible to manage before except by free flap. For us, perforator flaps have become the current first-line solutions for small to medium size loss of substances. Understanding of vascular physiology and surgical experience are essential in choosing indications, detecting perforators, and modeling flaps to be optimally positioned in the reconstructive decisional algorithm. New skills are needed to master this type of reconstruction and limit failures, which implies a learning curve not only for flap design, perforator detection and surgical procedure, but also for monitoring and management of complications. In this manuscript, we outline the concepts and principles of the majority of the pedicled perforator flaps available for coverage of the lower limb, based on experience of more than 400 perforator flaps suitable for this localization.

Candy Closure Technique for Chronic Open Infective Lateral Malleolus Bursitis

The aim of this study was to report the effectiveness of the Candy closure technique as a treatment for chronic open infective lateral malleolus bursitis. From June 2014 to March 2018, we performed the Candy closure technique as a treatment for chronic open infective lateral malleolus bursitis in nine patients without secondary operation. We first performed infectious tissue debridement to control infection, and if primary closure was not possible, we performed the Candy closure technique for small wounds. The duration of the wound prior to surgery varied from 4 weeks to 2 years. Seven cases were due to infection on the bursa and two cases were ulcer-type bursitis. All the wounds were small (average, 3.80 cm²; range, 2.25-4 cm²) and circular. Seven wounds showed complete healing at 4 weeks after surgery, one wound showed complete healing at 8 weeks after surgery, and one wound with infected state was lost to missing follow-up. Of the seven wounds that showed complete healing, one wound recurred 6 months after surgery. The Candy closure technique is a simple method for ensuring healing and coverage of chronic open lateral malleolus bursitis, especially for small wounds with dead space.

Reconstruction of fingers after electrical injury using lateral tarsal artery flap

Objective

Electrical injuries to the fingers account for the majority of total severe burns that occur each year. While several types of flaps have been used in covering finger defects, all have limitations or disadvantages. The purpose of this study was to introduce our clinical experiences of using the lateral tarsal artery (LTA) flap to successfully restore fingers after electrical injury.

Patients and methods

From 2005 to 2012, 10 patients with 14 severe electrical burns to their fingers, including six thumbs and four index and four middle fingers, were treated with LTA flap. The wound size ranged from 2.0×3.0 cm to 3.5×5.0 cm. The flap with free tendon graft was used to repair the tendon defect in four cases, free nerve graft was used to repair the feeling defect in two cases, and the flap with nerve was used to repair the feeling defect in two cases. All the patients were followed up for 3 months to 2 years.

Results

All skin flaps adhered successfully and there were no complications. All patients were satisfied with the esthetic appearance and functional outcome of the finger reconstruction.

Conclusion

LTA flap is a reliable method to restore fingers after severe electrical injuries.

Redefining the Vascular Classifications of the Lateral Supramalleolar Flap

BACKGROUND

The blood supply of the lateral supramalleolar flap (LSMF) generally comes from the perforating branch of the peroneal artery. However, the cutaneous branch may also receive blood from the anterior tibial artery. The main objective of the present study was to clarify the vascular anatomy of the LSMF.

METHODS

Anatomical dissections were performed on 28 perfused fresh cadaver legs. The cutaneous branches of LSMF were identified, and the anatomic relationship between the cutaneous branches and the peroneal and anterior tibial arteries was analyzed.

RESULTS

The vascular supply for LSMF was divided into 2 main types. A collateral inferolateral branch from the anterior tibial artery anastomosed with the perforating branch of the peroneal artery around the inferior tibiofibular angle, and the main cutaneous branch of the flap arose from this arterial anastomosis in 20 of 28 limbs (71.4%). The collateral inferolateral branch was absent or very small in the other 8 of 28 dissections (28.6%), and the cutaneous branches solely arose from the perforating branch of the peroneal artery. The anastomosis of the descending branch of the peroneal artery and anterior lateral malleolar artery was always (100%) found around the tibiotalar joint.

CONCLUSIONS

In addition to the perforating branch of the peroneal artery, the LSMF may also receive blood from the anterior tibial artery through the collateral inferolateral branch. New modified proximally based flaps could be designed, and caution is warranted for these variations when a distally based flap is performed.

Anatomical study of anterior supramalleolar artery and its potential application to design a bi-foliate fasciocutaneous flap

Purpose:

A further understanding of the anterior supramalleolar artery (ASMA) and its potential applications in reconstructive surgery.

Materials and Methods:

A total of 24 fresh lower limbs from fresh cadavers were injected with red latex for dissection. The type of origin, course, diameter of the pedicle, and the distance between the origin of the ASMA from the anterior tibial artery to the extensor retinaculum (O-R) were recorded. Bi-foliate fasciocutaneous flaps were harvested using the branches of the ASMA.

Results:

We found four types of origin of the ASMA, and we have accordingly classified them into four types. 10 of them were type A, 7 were type B, 6 were type C and 1 was type D. The mean O-R (origin of ASMA to retinaculum) distance was 2.0 ± 0.8 cm. The diameter of the medial branch (D1), the diameter of the lateral branch (D2), and the diameter of artery stem (D3) (only in type A) were 1.0 ± 0.2 mm, 0.8 ± 0.3 mm, 1.1 ± 0.2 mm, respectively. The mean pedicle length of the lateral flap (L1) and medial flap (L2) were 5.1 ± 1.0 cm and 3.7 ± 0.6 cm, respectively.

Conclusions:

The ASMA exists constantly with four different types of origin. Its sizable diameter and lengthy pedicle make it suitable for bi-foliate fasciocutaneous flap transfer.

Reconstruction of the lateral malleolus and calcaneus region using free thoracodorsal artery perforator flaps

Reconstruction of the lateral malleolus or calcaneus region is challenging because of poor vascularity, minimal presence of soft tissue, and difficulties with flap positioning during and after the operation. In many cases, local flaps are limited in terms of size, durability, and vascularity. Free tissue transfer can be useful for complicated wounds. We report here on the results of the reconstruction in this region using free thoracodorsal artery perforator flaps. Between October 2010 and October 2013, 16 cases of lateral malleolus or calcaneus defects were reconstructed using free thoracodorsal artery perforator flaps. The defects varied from 2 × 5 cm(2) to 12 × 16 cm(2), and the flaps from 3 × 5 cm(2) to 10 × 15 cm(2). Two cases were reconstructed using chimeric-pattern flaps. Only the superficial adipose layers were harvested for all the flaps, without further thinning or debulking process. Five cases with complications occurred, including three cases of partial necrosis of the flap and two cases of venous congestion caused by thrombosis and compression of the venous pedicle, and one flap was totally lost. The mean follow-up duration was 11.8 months. All the patients were able to wear shoes. All but one were able to walk. The thoracodorsal artery perforator flap can be made super-thin, allowing patients to wear shoes, and it can be harvested in a chimeric-pattern for complex defects. Therefore, it may represent a viable alternative choice for the reconstruction of the lateral malleolus and calcaneus region.

[Flaps for soft tissue defect closure in the distal lower leg]

Soft tissue defects in the distal lower leg region are challenging to treat, especially in trauma cases. To achieve early closure of the defect, pediculated adipofascial or muscle flaps can be used as well as free flaps. The pediculated adipofascial suralis flap has a reliable blood supply and a broad radius so this flap can be used for almost every defect location on the distal lower leg except for defects larger than 10 × 10 cm. The donor site defect does not lead to major problems and is well tolerated. The soleus flap can cover defects in the middle third and proximal distal third of the lower leg with its muscle. The donor site defect is occasionally associated with reduced calf functioning but is tolerated well most of the time. Because of these advantages, the pediculated adipofacial suralis flap and the soleus muscle flap can be used instead a microvascular free flap for the closure of defects in the distal lower leg region.

[Lateral supramalleolar flaps for reconstruction in the ankle and foot]

OBJECTIVE

Defect reconstruction by transposition of well-vascularized thin and pliable skin.

INDICATIONS

Defect coverage involving the antero- and dorsolateral distal one third of the lower leg, the dorsolateral and dorsomedial hindfoot and dorsal midfoot.

CONTRAINDICATIONS

Severe peripheral arterial occlusive disease (PAOD), previous trauma at the anterolateral aspect of the lower leg and foot.

SURGICAL TECHNIQUE

Lateral fasciocutaneous supramalleolar flap with orthograde blood flow, fasciocutaneous lateral supramalleolar perforator flap with orthograde blood flow, adipofascial lateral supramalleolar flap with orthograde blood flow, lateral fasciocutaneous supramalleolar flap based on the lateral tarsal artery with retrograde blood flow, lateral fasciocutaneous supramalleolar flap based on the anterolateral malleolar artery with retrograde blood flow according to Oberlin.

POSTOPERATIVE MANAGEMENT

"Tie over" dressing for grafting site for 5 days (healing of split/full-thickness skin graft), complete immobilization of the lower leg for 7 days in a dorsal plaster splint (ensure that there is no pressure on the flap), progressive increase of range of motion after 1 week, postoperative standardized compression therapy, combined with scar therapy (silicone sheet).

RESULTS

Reliable, excellent functional and aesthetic results with thin skin in small to midsize defects. Increasing morbidity of grafting site in larger flaps and risk of neuroma when the superficial peroneal nerve was exposed.