Distally Based Perforator Medial Plantar Flap: A New Flap for Reconstruction of Plantar Forefoot Defects

Reverse-flow Flaps of the Medial Plantar Region: Review of the Literature With Case Report

Background

Many variations of the reverse flap design elevated on the medial plantar region have emerged since its introduction. Our aim was to review the literature to provide a broader understanding of the various iterations of the reversed blood-flow flap raised on the medial plantar region. Second, we wished to appraise the reverse medialis pedis flap by review of the literature and presentation of a case report.

Methods

A review of the literature was conducted regarding the reversed blood-flow flap elevated in the medial plantar region. The diverse types of vascular axis and retrograde blood-flow origin of the reverse flap in the medial plantar region were categorized. A clinical case of the reverse medialis pedis flap with step-by-step flap elevation and description of key landmarks are presented.

Results

Our literature review identified 38 publications pertaining to retrograde flow flaps in the medial plantar region. The reverse-flow anatomy derived from these publications was categorized based on vascular axis (pedicle) and retrograde blood-flow origins; Only 5 publications included the reverse medialis pedis flap in their article while 3 papers focused on detailed anatomic study and case series on this flap.

Conclusions

The reverse medial plantar artery flaps come with multiple flap designs depending on which antegrade flow artery is ligated and what anastomotic vascular origin is supplying the reversed blood flow. The reverse medialis pedis flap based on the superficial medial plantar artery with anastomosis to the first plantar metatarsal artery deserves consideration as an option for small defects of the great toe metatarsophalangeal joint.

Plantar forefoot reconstruction: A proposal of a management algorithm based on a case series analysis: Plantar forefoot reconstruction

BACKGROUND

Several loco-regional flaps have been described for plantar forefoot coverage. We, herein, report our single-centre experience in plantar forefoot reconstruction and propose a decision-making process based on the defect's size.

METHODS

This is a retrospective case series study of all patients who underwent plantar forefoot reconstruction in a 10-year period. We propose a treatment algorithm, based on the defect size. Defects are classified into small, moderate and large. Small defects (<10cm²) can be covered with the hemi-pulp toe flap. Patients with moderate defects (10-25cm²) can be treated with the reverse medial plantar artery flap (MPAF) from the instep area. For large defects (>25cm²), we recommend regional flaps, that is the distally based sural flap (DBSF) from the ipsilateral calf, or free flaps, such as the anterolateral thigh flap (ALT) or the skin-grafted gracilis flap.

RESULTS

The data of 51 patients were collected and analysed. The median age was 58 years (range 19-84). Nine patients had small defects and underwent hemi-pulp toe flap reconstruction. Three patients presented with moderate defects that were covered with reverse MPFs. The vast majority of the patients (39 patients) had large defects. Of these, eight cases were treated with DBSF and 31 cases with free flaps. Free flap transfers were successful in 97% of the cases. Overall complication rate was 25%.

CONCLUSION

We conclude that local flaps should be preferred in plantar forefoot reconstruction as they provide like-tissue for small to moderate defects, for large defects regional flaps or free flaps were indicated. A defect-based approach can facilitate the decision-making process.

Distally Based Medial Plantar Flap: A Classification of the Surgical Techniques

The proximally based medial plantar flap is considered to be the reference standard for heel reconstruction. Although less well-studied, a distally based medial plantar flap is a suitable alternative when used to cover a distal foot defect, especially of the hallux, first metatarsal, or metatarsophalangeal joint. Our objective was to provide a complete description and propose a classification of the different surgical procedures used to harvest this flap. A review of the data reported in the MEDLINE database until May 2017 concerning the distally based medial plantar flap was performed. We have illustrated the different surgical procedures through a case series. Three approaches or "types" of flap have been described, and we have proposed a classification for reconstructive surgeons. In type 1, the plantar pedicle is ligatured before division into the medial and lateral plantar artery. In type 2, the medial plantar pedicle is cut proximally just after division. In type 3, the flap is harvested to include the fasciocutaneous perforator vessels, as an advancement flap or a propeller perforator flap. A distally based medial plantar flap affords adequate and reliable coverage of the weightbearing zone. Because the donor site drawbacks are minimal, this flap is a useful option for distal foot reconstruction, and reconstructive surgeons should remember this flap. The type 1 flap appears to be associated with a minimal risk of flap necrosis, even in those with diabetes or arteriopathy, and can cover even the most distal defect.

Anatomy of medial plantar superficial branch artery perforators: Facilitation of medial plantar superficial branch artery perforator (MPAP) flap harvesting and design for finger pulp reconstruction

BACKGROUND

Medial plantar artery perforator (MPAP) flap was proposed as proper option for finger pulp reconstruction. To provide the previously unavailable vessel information required for this small flap design, this study aimed to gather all necessary anatomy of MPA, MPAP, and their territories of blood supply to apply in clinical MPAP flap reconstruction minimizing perforator injury.

METHODS

Dissection of 30 Thai cadaveric feet for visualizing superficial branch of MPA and its perforators (MPAP) using acrylic dye cannulation were performed. Diameter, length, number of branches, course, distributing areas of these vessels, and also their areas of blood supply were recorded in relation to specified landmarks, eg, C-MTH line; medial calcaneal tuberosity to plantar side of the first metatarsal head and S point; emerging point of superficial branch of MPA from deep fasciae into subcutaneous layer.

RESULTS

Average diameter of MPA at its origin and total length are 1.63 ± 0.3 and 52.8 ± 16.1 mm, respectively. It provides 1-3 perforators, with an average size and length of 0.36 ± 0.11 and 23.2 ± 5.47 mm, respectively. Its distribution is mostly in the posteromedial quadrant within 50 and 30 mm from the midpoint of C-MTH line and the S point, respectively. The estimated perforator flap area is 2.5 cm × 1.5 cm and 4.5 cm × 2.5 cm for single and double perforators, respectively.

CONCLUSIONS

MPAP flap was proved as another ideal option for finger pulp reconstruction. Its limitation is small size of perforators but this can be overcome by using MPA for microsurgical anastomosis instead.

Reverse-Flow Intrinsic Fasciocutaneous Island Flaps in Foot Reconstruction

Reconstruction of soft tissue defects in the foot remains a challenge due to its specialized tissue for weightbearing and ambulation. Considering the principle of replacing "like with like," adjacent soft tissues would be a best option for a donor site. Although several kinds of reverse-flow island flaps for the lower leg have been well described, intrinsic foot reverse flow flaps have been rarely reported. We describe 3 kinds of reverse-flow intrinsic fasciocutaneous flaps (RIFFs) for foot reconstruction. From September 2012 to August 2015, a retrospective study was done on case notes of all patients who had a RIFF for coverage of soft tissue defects within the foot following trauma or tumor ablation. A total of 7 patients were included in this study, with an average of 5 × 3.5 cm sized defects in the forefoot, second and third web space, and sole, which were reconstructed with RIFF. All flaps were well perfused and recovered excellent function of the foot with satisfactory aesthetics and minimal limitations in range of motion. However, one case showed a complication of venous congestion, due to remnant scar tissues, which resolved after medical leech application. Donor defects healed completely with split thickness skin grafting in all cases. Soft tissue defects within the foot were repaired successfully by RIFF. In spite of its technical challenges, it is a reliable one-stage procedure requiring no microsurgical anastomosis. Precise vascular evaluation of the reverse inflow has to be preceded for satisfactory outcome of RIFF.

Reconstruction of soft-tissue lesions of the foot with the use of the medial plantar flap

Objective

To study use of the medial plantar flap for reconstruction of the heel and foot.

Method

The authors share their clinical experience with the use of the medial plantar artery flap for coverage of tissue defects around the foot and heel after trauma. Twelve cases of medial plantar artery flap performed from January 2001 to December 2013 were included.

Results

Of the 12 patients, ten were male and two were female. The indications were traumatic loss of the heel pad in ten cases and the dorsal foot in two cases. All the flaps healed uneventfully without major complications, except one case with partial flap loss. The donor site was covered with a split-thickness skin graft. The flaps had slightly inferior protective sensation compared with the normal side.

Conclusion

From these results, the authors suggest that the medial plantar artery flap is a good addition to the existing armamentarium for coverage of the foot and heel. It is versatile flap that can cover defects on the heel, over the Achilles tendon and plantar surface, as well as the dorsal foot. It provides tissue to the plantar skin with a similar texture and intact protective sensation.

Anatomic basis and clinical application of the distally based medialis pedis flaps

BACKGROUND

Soft-tissue defects of the forefoot are difficult to cover adequately, particularly, although multiple options for reconstruction are available. This study especially focused on the vascularization of the medial side of the foot and the determination of the contribution of the nutrient vessels to medialis pedis flap viability.

METHODS

Thirty cadavers were available for this anatomical study. Microdissection was conducted under a microscope, and details of the course and distribution and the communication of the first plantar metatarsal artery with the fascial vascular network of the medial side of the foot were recorded. Clinically, six cases of soft-tissue defects at the forefoot region were reconstructed with distally based medialis pedis flap.

RESULTS

The perforator of the first plantar metatarsal artery pierces in the superficial fascia of the medial aspect of the foot 2.2 ± 0.7 cm proximal to the first metatarsophalangeal joint, vascularize the skin of the medial plantar region. The anatomical study showed that the vasculature pattern could roughly be classified into two types. In terms of clinical application, all flaps completely survived, and one patient had partial loss of skin graft.

CONCLUSION

The perforators of the medialis pedis flap are presented constant. The forefoot region can be repaired by the distally based medialis pedis flap on the perforator of the medial plantar artery of the hallux or the first plantar metatarsal artery perforator with medial plantar vein, medial plantar cutaneous nerve and nutrient vessels.

Traumatic Forefoot Reconstructions With Free Perforator Flaps

The forefoot is critical to normal walking; thus, any reconstruction of forefoot defects, including the soft tissues, must be carefully done. The free perforator flap, with its physiologic circulation, lower donor site morbidity, and minimal thickness is the most popular technique in plastic and microsurgery, and is theoretically the most suitable for such forefoot reconstruction. However, these flaps are generally recognized as more difficult and time-consuming to create than other flaps. In 41 patients with traumatic forefoot defects, we reconstructed the forefoot integument using 5 types of free perforator flaps. The overall functional and cosmetic outcomes were excellent. Three flaps required repeat exploration; one survived. The most common complications were insufficient perfusion and the need for second debulking. The key to our success was thoroughly debriding devitalized bone and soft tissue before attaching the flap. Forefoot reconstruction with a free perforator flap provides better function, better cosmesis, better weightbearing, and better gait than the other flaps we have used.

Reconstruction of great toe soft-tissue defect with the retrograde-flow medial pedis island flap

BACKGROUND

Several investigators have reported their clinical experience with medial pedis flaps for reconstruction of soft-tissue defects of the distal forefoot. However, they had only a few reports where this flap was used to repair soft-tissue defects of the great toe. Thus, reconstruction of soft-tissue defects of the great toe remains a challenge in reconstructive surgery. The authors describe the use of the medial pedis island flap to cover this region.

METHODS

This study was divided into two parts: an anatomic study and clinical application. In the anatomic study, 48 cadaveric feet were injected with latex, and then the main vessels distributed at the medial aspect of the foot were observed. Clinically, retrograde-flow medial pedis island flaps were harvested to cover the soft-tissue defects of the great toe in eight cases.

RESULTS

An anatomic study revealed that the arterial circle under the first metatarsophalangeal joint and the arterial network on the surface of the abductor hallucis were responsible for the blood supply of the medial region of the foot. The diameter of the pedicle was great, and the pedicle was longer than previously reported. In terms of clinical application, all flaps were successful, without any significant complications.

CONCLUSIONS

Using the arterial circle under the first metatarsophalangeal joint, the medial pedis island flap has a reliable retrograde blood supply. This flap should be considered as a preferential way of reconstructing soft-tissue defects of the great toe.

CLINICAL QUESTION/LEVEL OF EVIDENCE

Therapeutic, V.

Reconstruction of lateral forefoot using reversed medial plantar flap with free anterolateral thigh flap

Skin defects of the heel have frequently been reconstructed using the medial plantar flap; however, forefoot coverage has remained a challenge, because the alternatives for flap coverage have been very limited. We describe a case of malignant melanoma on the lateral forefoot that was radically removed and reconstructed successfully with a distally based medial plantar flap, together with a free anterolateral thigh flap. The advantages of this flap include that it does not reduce the vascular supply to the foot owing to reconstruction of the medial plantar vascular systems, reduces the risk of flap congestion, minimizes donor site morbidity, and enables the transport of structurally similar tissues to the plantar forefoot. We believe this technique is a reasonable reconstructive option for large lateral plantar forefoot defects.

Reconstruction of a child's forefoot defect using a distally based pedicled medial plantar flap

This report describes a case of a 10-year-old boy who received a distally based, pedicled medial plantar artery flap to cover a defect on the distal lateral side of his right foot. The defect resulted from amniotic constriction. The flap served as defect coverage and was kept viable solely by the distal medial plantar vessels. Use of this particular kind of flap proves advantageous in that it provides good protection in the weight-bearing area of the foot, while causing only a minor donor site defect.

Reconstruction of distal forefoot burn defect with retrograde medial plantar flap

Burn reconstruction of forefoot remains as a difficult challenge, because the local flap alternatives are limited. We evaluated the efficiency of distally based medial plantar fasciocutaneous island flap in the coverage of forefoot defects resulting from release of toe contracture and burn debridement. Four patients with toe contractures and two patients with third degree burn in forefoot were treated between June 2004 and February 2006. The mean follow-up period was 10.4 months. The flaps were elevated as with a fasciocutaneous base on the distal medial plantar artery. The dimensions of the flaps ranged from 4cmx3cm to 5cmx4cm. The skin over the pedicle was included as a part of flap in three cases. Concomitant vein of the pedicle was anastomosed with the first plantar digital vein in four cases. In the early postoperative period, one flap used to cover third degree burn due to high-voltage electric injury was lost completely. We concluded that this flap was an appropriate alternative reconstructive option for the forefoot defect. Including skin and subcutaneous tissue over the pedicle to flap protects the pedicle against kinking and compression. Venous supercharging of the flap improves venous drainage.