The dorsal metatarsal artery perforator flap.

Few options exist for the resurfacing of web-space and small soft tissue defects of the dorsum of the distal foot. The study examines the anatomy of the second to fourth dorsal metatarsal arteries in 16 fresh frozen cadavers to determine if the anatomy correlates to that in the hand, permitting the design of local flaps based on perforators of these vessels. A clinical case is also presented, illustrating the efficacy of such a perforator-based flap.Sixteen Asian cadaveric lower limbs were used for this study. The specimens were prepared with latex dye injection. Dissection under loupe magnification was carried out to determine the position and caliber of the cutaneous perforators from the dorsal metatarsal arteries, and the spread of the latex dye in the skin from these cutaneous perforators. One clinical case illustration of this perforator-based flap for distal foot defect resurfacing is presented.In our cadaveric study, each second to fourth dorsal metatarsal artery had between 2 and 5 cutaneous perforators with calibers of 0.5 to 0.7 mm in diameter. The most distal cutaneous perforator was present consistently, always arising between the heads of the respective metatarsals.In conclusion, the vascular anatomy of the second to fourth dorsal metatarsal arteries is similar to that in the hand, thus allowing for the design of reliable perforator-based flaps for distal foot resurfacing.

A chimaeric-pattern flap design for implantable Doppler surrogate monitoring: a novel placement technique.

INTRODUCTION AND AIM: Postoperative flap monitoring is a vital aspect of free tissue transfer in order to detect early vascular compromise and to enable early flap salvage. The implantable Doppler monitoring system is one of many monitoring devices used to ensure accuracy and reduce unnecessary flap explorations. However, there are a number of concerns with its use, namely tension on the anastomosis, possible vessel constriction and false-negative detection. This study aimed to alleviate these concerns, by introducing a new method of placing the implantable Doppler probe on the adjacent vessel limb of a chimaeric flap. This is illustrated by a case series of chimaeric free tissue flaps that allow this surrogate placement of the Doppler probe. METHODS: The flap is raised in a chimaeric fashion, with a main perforator pedicle to the skin or muscle paddle for the main reconstructive purpose and a side branch from the main pedicle going to a smaller adipofascial or muscle flap for monitoring. This branch vascular pedicle leading to the chimaeric tissue is kept sufficiently long to enable placement of the Doppler cuff and prevent turbulence. The probe of a Cook-Swartz implantable Doppler system is placed around the branch pedicle, approximately 5 mm from the branching point, and secured with a vessel clip. This is then secured away from the major vessels of the main free flap. Removal of the probe's crystal and wire is easily done with a single gentle traction on postoperative day 7. RESULTS: Five cases of chimaeric free flaps were performed with this manoeuvre: three thoracodorsal perforator chimaeric flaps for head-and-neck or extremity reconstruction, one latissimus dorsi neuromuscular chimaeric flap for facial reanimation and one digastric lymph node transfer for the treatment of lower limb lymphoedema. The Doppler system showed a low but sustained oscillating flow in all cases indicating vascular patency, with minimal flow interference from other large-calibre vessels. There was no discernible kinking on the anastomosis. There were no complications encountered during probe removal. This postoperative monitoring manoeuvre was done successfully with good results. CONCLUSION: The monitoring equipment is very sensitive to any flow disturbance due to positional changes in the head-and-neck region or the extremities and is able to detect flow changes in buried flaps postoperatively. Chimaeric flap composition is easier now than before because of perforator-oriented pedicle dissection, and surrogate Doppler monitoring is one more application of the chimaeric flap. This novel chimaeric fashion of implantable Doppler probe placement is a good surrogate measure of flow in the main pedicle.

Blindness resulting from orbital cellulitis following rhinoplasty.

Ophthalmic complications occurring after non-ophthalmic surgery are rare. We present a case of orbital cellulitis in a 24-year-old woman, who had undergone augmentation rhinoplasty in combination with breast augmentation. Symptoms included pain, swelling, erythema and eventual loss of vision in the left eye. Intravenous administration of antibiotics did not halt the rapid progression of this infection. On the sixth postoperative day, the patient underwent left-orbital evisceration to prevent the spread of infection to other organ systems. Despite aggressive therapy, the sequela was permanent, unilateral blindness. Orbital cellulitis in aesthetic surgery is extremely rare. In patients undergoing rhinoplasties that may be prolonged due to other concomitant cosmetic procedures, aseptic preoperative preparation and careful monitoring for signs of orbital infection are recommended.

Accelerated osteomesh resorption: a case report.

Facial fractures occur commonly as a result of blunt trauma from road traffic accidents, assaults, and sporting injuries. Orbital floor fractures form a significant proportion of these and when large enough, the defect often requires surgical reconstruction of the floor to prevent orbital content herniation. Here, we present a case of a 28-year-old gentleman, who sustained an orbital floor fracture from a soccer-related injury. The resulting floor defect was surgically repaired using an osteomesh that was hand-cut to size. He developed delayed enophthalmos and entrapment of the inferior rectus muscle due to early resorption of the osteomesh, requiring revision surgery.