Hybrid Regenerative Therapy for Successful Reconstruction of an Infected Traumatized Diabetic Foot Wound.

Diabetic foot ulcers are a significant complication of diabetes, affecting millions globally, and require appropriate antibiotics, surgical debridement, wound care, and metabolic optimization for management. This article presents an innovative hybrid regenerative therapy for reconstructing an infected, traumatized foot wound of a 62-year-old man with diabetes mellitus who presented with a week-old injury after a car accident. At presentation, he had a 14 × 10 cm dorsal foot wound with skin necrosis, pus discharge, and bony instability owing to partial fractures and joint dislocations. Antibiotics were administered to treat multidrug-resistant bacteria and followed by surgical debridement and the application of a portable Velnext negative pressure wound therapy device. Once the wound condition stabilized, hybrid regenerative therapy was performed weekly. Six milliliters platelet-rich plasma and 6 mL platelet-poor plasma were prepared from 27 mL of venous blood mixed with 3 mL sodium citrate and injected into the tendons, soft-tissues, and muscles. Next, the exposed bones and tendons were covered with platelet-rich fibrin and semi-occlusive membranes, and a Velnext negative pressure wound therapy device was applied over them. The wound improved progressively during the subsequent 6 weeks and was finally covered with a split-skin graft. The patient had a successful 18-month postoperative period until now with stable grafts, anatomical restoration, and excellent foot functionality. Thus, hybrid regenerative therapy, encompassing several prevalent methods for healing wounds, has excellent benefits for treating complex diabetic foot ulcers.

Tissue-engineered Minimalistic Reconstruction of a Severely Crushed Fingertip.

The goals of treatment for fingertip injuries are maximising digital length, tactile sensation, pulp padding, and fingertip appearance while minimising complications like infection and amputation. Currently, terminalisation, healing by secondary intention, and flap surgeries are widely used for crushing fingertip injuries, but they have their own set of issues and limitations. We present a tissue-engineered method by combining platelet-rich fibrin injections with stacked-up layers of synthetic biodegradable temporising matrix to treat a severely crushed fingertip. This novel therapy minimised reconstructions while successfully regenerating new soft-tissues. Soft-tissue regeneration within the stacked-up biodegradable matrix achieved adequate volume, sensation, function, and mobility of the newly reconstructed fingertip while maintaining its skeletal length. Notably, the regenerated fingertip allowed the patient to resume work normally as a busy software engineer. Thus, minimalistic fingertip reconstruction not only prevented a disability, but also served as a viable alternative to major reconstructive surgeries.

Enxertos compostos de gordura para correção de distrofia facial em caso de esclerodermia localizada / Composite fat grafts for correcting facial dystrophy in a case of localized scleroderma

A esclerodermia localizada (morfeia linear) é uma doença rara que causa distrofia e assimetria faciais em mulheres jovens. É relatado o caso de uma paciente de 20 anos que foi tratada com enxertos compostos de gordura. Após a coleta do lipoaspirado de gordura subcutânea profunda, a microgordura e a nanogordura não filtrada foram processadas separadamente para formar enxertos compostos de gordura. Estes foram meticulosamente transplantados em camadas, para reconstruir o subcutaneo da face da paciente. Após um ano, observou-se boa pega de gordura com correção bem-sucedida da assimetria e restabelecimento do equilíbrio facial.

Localized scleroderma (linear morphea) is a rare disease that causes facial dystrophy and asymmetry in young women. We report the case of a 20-year-old female patient who was treated with novel composite fat grafts. After extracting lipoaspirate from deep subcutaneous fat, the microfat and the unfiltered nanofat were processed separately, and amalgamated, obtaining composite fat grafts. These were meticulously transplanted layer by layer to rebuild the subcutaneous tissue of the patient's face. After one year, a good volume of fat retention was observed with successful correction of asymmetry and restoration of facial balance.

Minimally Invasive Successful Reconstruction of a Severely Traumatized Upper Extremity Using Platelet-Rich Plasma and Tissue Scaffold: A Case Report.

Minimally invasive reconstruction combines principles of tissue engineering and regenerative medicine for healing complex wounds. This approach was successfully demonstrated on a 64-year-old diabetic and hypertensive male patient, who was brought unconscious to our emergency after surviving an automobile collision with severe brain and right-dominant upper extremity injuries. Uncontrolled hyperglycemia, severe anemia, diffuse axonal brain injury, wrist drop, and loss of thumb extension and abduction were noted. Extensive degloving, skin necrosis, extensor and flexor forearm muscle crush injuries, and ruptured extensor tendons were observed. Serial wound debridement combined with platelet-poor plasma injection into the muscles, platelet-rich plasma injections into the tendons and subcutis, and low-negative pressure wound therapy were performed sequentially to salvage the injured soft-tissues. Improvements were noticed during the second exploration after 5 days. Surviving muscles showed adequate vascularization and revival of innervation during the third exploration after another 5 days. Thereafter, absorbable synthetic tissue scaffold was applied over a sizeable 270 cm 2 wound as a flap-alternative. Tissues regenerated well within the scaffold during the next 2 months, halving the wound area to 132 cm 2 . A thick split-skin graft was applied over the remaining granulating neodermis, which "took" completely. Six months postoperatively, the patient regained most hand functions and performed all activities satisfactorily, while the grafted area appeared almost identical to surroundings. Minimally invasive reconstruction thus produced satisfying results with fewer shorter simpler surgeries, minimal anesthesia, short-duration hospitalization, lower health care costs, lesser risks, and excellent patient-reported outcomes.

Minimally Invasive Reconstruction of an Allen Three Traumatic Thumb Injury with Platelet-rich Fibrin and Stacked Dermal Regeneration Template.

Introduction: The human thumb is critical for performing complex movements with the hand. Injuries to the thumb can significantly impact an individual's livelihood, and those with exposed bones or tendons have traditionally been treated with terminalization or reconstructive flap surgeries. However, many patients feel that their results could be better. Case Report: We attempted a novel approach stacking multiple layers of a dermal regeneration template in a quest for better results. A young male teacher presented to our clinic with a 2-day-old severely injured thumb tip. Attempting to regenerate the lost fingertip, we first stacked the inner absorbable layers of the template layer-by-layer over the exposed bone and raw areas. Then, we injected platelet-rich fibrin (PRF) around the wound intraoperatively and at weekly intervals for a month to encourage soft-tissue development. After 6 months, we observed near-total soft-tissue development and good anatomical restoration of the lost thumb tip. Sensation returned to near-normal levels, with full functional recovery of the thumb and hand. Conclusion: Our minimally invasive approach to reconstructing the distal thumb after an Allen Type 3 traumatic injury, utilizing PRF and a regenerative template, is a safe and effective alternative to traditional treatments. This innovative method has improved upon previously described results and may offer hope to many patients with severe thumb injuries.

Life-Threatening Panfacial Wild Dog Bites in a Child.

Infants and toddlers can sustain grievous craniofacial injuries after dog bites, some of which may be life-threatening. An 18-mo-old male child presented to our emergency department with complex panfacial wounds after being bitten by an unvaccinated wild dog 6 h earlier. Primary management, hemostasis, and rabies postexposure prophylaxis were performed near his home. Initially, he was resuscitated from severe hemorrhagic shock and anemia in a pediatric intensive care unit. After stabilization, early primary repair of all facial injuries was performed. Surgical exploration revealed multiple full-thickness avulsions, lacerations, nasal bone fractures, facial muscle injuries, and right ear necrosis. Gentle tissue-handling and meticulous reconstruction satisfactorily restored his facial soft-tissue contours about 64 h after the bite injury. Postoperatively, recovery was uneventful except for localized soft-tissue infection caused by multidrug-resistant Pseudomonas, which resolved with appropriate antibiotics. Nine months later, his face and ear appeared almost symmetrical with well-settled scars. Psychological recovery progressed smoothly, excepting few incidences of panic attacks that were triggered by loud noises. Here, we observed that early primary reconstruction of severely mauled soft tissues after wild dog bites, performed within 72 h with adequate precautions, safely produced satisfying long-term outcomes.

Minimalistic reconstruction of exposed skull in a complex craniovertebral polytrauma.

BACKGROUND: In stable craniovertebral injuries complicated by polytrauma, rigorous spinal immobilization is essential for neuroprotection. Scalp and forehead reconstruction in these circumstances are safest when performed under local anesthesia, maintaining cervical immobilization. CASE DESCRIPTION: A sizeable 10 × 6.5 cm forehead defect was reconstructed utilizing regenerative principles under local anesthesia and sedation in a 54-year-old woman. After adequate debridement of gangrenous soft tissues, exposed outer skull bones were trephined, forehead defect covered with a synthetic biomaterial, and the patient was discharged thereafter. Granulating neodermis regenerated within the biomaterial over the next 6 weeks. Weekly platelet-rich plasma injections along the wound margins facilitated wound regeneration. Dimensions reduced by two-thirds to 6.5 × 3.5 cm with wound regeneration and contraction, while granulating neodermis covered the remaining skull-bones. Split skin-grafting over the neodermis ensured satisfying long-term results, with similar color, texture, soft-tissue thickness, and sensation. Multiple occipitocervical, spinal, scapular, and rib fractures healed well with strict immobilization. CONCLUSION: Good long-term results were achieved with significantly reduced dangers, complications, hospitalization, and costs than traditional reconstructive flap surgeries. Minimalistic reconstruction utilizing tissue engineering and regenerative medicine principles appears beneficial for patients with grave spinal injuries.

Tissue Engineered Successful Reconstruction of a Complex Traumatized Lower Extremity.

Introduction: Tissue engineered reconstruction is a minimally invasive approach for healing major complex wounds successfully. It combines accurate, conservative debridement with a specially adapted suction method, platelet-rich plasma (PRP) injections, and biomaterial application to salvage injured tissues and grows new soft tissues over wounds. Case Presentation: A healthy young man in his early 30s presented to our emergency department with complex knee-thigh injuries following a high-velocity automobile accident. Degloved anterolateral thigh, severe thigh muscle injuries, and ruptured extensor patellar mechanism were observed. Accurate conservative (as opposed to radical) debridement and PRP injections salvaged the injured muscles and tendons. Specially carved reticulated foam wrapped around the injured ischemic muscles, followed by low negative, short intermittent, cyclical suction therapy. Wound exploration 4 days apart revealed progressive improvements with considerable vascularization of the injured soft tissues within 2 weeks. Thereafter, meticulous reconstruction of the salvaged muscles and tendons restored anatomical congruity. An absorbable synthetic biomaterial covered the sizeable open wound with vast areas of exposed tendons. Five weeks later, exuberant granulating tissue ingrowth within the biomaterial filled up the tissue defect. A split-skin graft covered the remaining raw areas, which "took" completely. Early rehabilitation enabled the patient to return to active work, play contact sports, and perform strenuous activities effortlessly. Conclusion: Minimally invasive tissue engineered reconstruction is a novel approach using a series of simple minimally invasive procedures. It lessens the duration of surgery and anesthesia, maximizes soft-tissue salvage, lowers morbidity, minimizes hospitalization, saves costs, and improves the patient's quality of life significantly.