【Abstract】 Objective To investigate the effectiveness of the vacuum sealing drainage (VSD) technique with split middle thickness skin replantation for the treatment of severe skin closed internal degloving injury (CIDI). Methods Between July 2008 and April 2011, 16 patients with severe skin CIDI were treated. There were 11 males and 5 females, aged 17-56 years (mean, 28 years). Injury was caused by traffic accident in all cases. The time between injury and operation was 2-8 hours (mean, 5 hours). Peeling skin parts included the upper limb in 3 cases and the lower limb in 13 cases. The range of skin exfoliation was 5%-12% (mean, 7%) of the body surface area with different degree of skin contamination. After thorough debridement, exfoliative skin was made split middle thickness skin graft for in situ replantation, and then VSD was performed. Results After 7 days of VSD therapy, graft skin survived successfully in 14 cases; partial necrosis of graft skin occurred in 2 cases, and was cured after thorough debridement combined with antibiotics for 7 days. All patients were followed up 6-18 months (mean, 12 months). The appearance of the limb was satisfactory without obvious scar formation, and the blood supply and sensation were normal.The joint function was normal. Conclusion For patients with severe skin CIDI, VSD treatment combined with split middle thickness skin replantation can improve the local blood circulation of the limb, promote replantation skin survival, and shorten healing time of wound. The clinical effectiveness is satisfactory.
Objective To observe the effectiveness of vacuum seal ing drainage (VSD) combined with anti-takenskin graft on open amputation wound by comparing with direct anti-taken skin graft. Methods Between March 2005 andJune 2010, 60 cases of amputation wounds for limbs open fractures were selected by using the random single-blind method.The amputation wounds were treated with VSD combined with anti-taken skin graft (test group, n=30) and direct anti-takenskin graft (control group, n=30). No significant difference was found in age, gender, injury cause, amputation level, defect size,preoperative albumin index, or injury time between 2 groups (P gt; 0.05). In test group, the redundant stump skin was usedto prepare reattached staggered-meshed middle-thickness skin flap by using a drum dermatome deal ing after amputation,which was transplanted amputation wounds, and then the skin surface was covered with VSD for continuous negative pressuredrainage for 7-10 days. In control group, wounds were covered by anti-taken thickness skin flap directly after amputation, andconventional dress changing was given. Results To observe the survival condition of the skin graft in test group, the VSDdevice was removed at 8 days after operation. The skin graft survival rate, wound infection rate, reamputation rate, times ofdressing change, and the hospital ization days in test group were significantly better than those in control group [ 90.0% vs.63.3%, 3.3% vs. 20.0%, 0 vs. 13.3%, (2.0 ± 0.5) times vs. (8.0 ± 1.5) times, and (12.0 ± 2.6) days vs. (18.0 ± 3.2) days, respectively](P lt; 0.05). The patients were followed up 1-3 years with an average of 2 years. At last follow-up, the scar area and grading, and twopointdiscrimination of wound in test group were better than those in control group, showing significant differences (P lt; 0.05).No obvious swelling occurred at the residual limbs in 2 groups. The limb pain incidence and the residual limb length were betterin test group than those in control group (P lt; 0.05). Whereas, no significant difference was found in the shape of the residual limbs between 2 groups (P gt; 0.05). In comparison with the contralateral limbs, the muscle had disuse atrophy and decreasedstrength in residual limbs of 2 groups. There was significant difference in the muscle strength between normal and affected limbs(P lt; 0.05), but no significant difference was found in affected limbs between 2 groups (P gt; 0.05). Conclusion Comparedwith direct anti-taken skin graft on amputation wound, the wound could be closed primarily by using the VSD combined withanti-taken skin graft. At the same time it could achieve better wound drainage, reduce infection rate, promote good adhesion ofwound, improve skin survival rate, and are beneficial to lower the amputation level, so it is an ideal way to deal with amputationwound in the phase I.
Objective Gunshot wound spreads to the surrounding tissues and organs, it is difficult to debride and easy to infect. The conventional treatment is thorough, extensive debridement, fully open drainage, which often causes normal tissue damage and compl ications. To evaluate the effectiveness of vacuum seal ing drainage (VSD) treating thepenetrating wound in porcine extremity by MRI and pathological methods so as to provide theoretical basis for future cl inical use. Methods Eight healthy adult pigs, weighing (45 ± 5) kg, were selected. Eight pairs of hind l imb penetrating wounds (16 wounds) were made by using Chinese-made 95-type rifle at 25 meters distance, which were randomly divided into experimental group (left side, n=8) and the control group (right side, n=8). After debriding and disinfecting the penetrating wounds at 6 hours after injury, wounds were treated with VSD in experimental group. The ball istics exports of the wounds were covered with single-layer gauze and imports were directly sutured and covered with sterile gauze in control group. The trajectory and the general condition of the adjacent skin were observed. MRI and histological observation were taken at 5, 24, 48, and 72 hours after injury, bacterial counting analysis was done at 0, 12, 24, 48, and 72 hours after injury. Results The aperture of the trajectory exit and entry were (5.00 ± 2.50) cm and (0.30 ± 0.15) cm immediately after injury. The wound surface was clean, rosy without leakage and swell ing after 72 hours in experimental group; wound and adjacent tissue were swell ing obviously, pus, muscle necrosis and exfol iative tissue was observed, and deep defect cavity at the trajectory exit could be seen in control group. MRI showed that pairs of l inear low signal in T1WI and T2WI was seen in trajector of experimental group at 5 hours after injury, and signal in T1WI gradually increased at disrupted area and tissue deformation area at 24, 48, and 72 hours; in control group, low signal in T1WI was observed at 5 hours after injury, and signal in T2WI gradually increased and a clear boundari between edema and surrounding tissue, and the increase of signal in T1WI was not obvious at 24, 48, and 72 hours. The histological observation showed that wound was dominated by effusion at 5 hours after injury, granulation tissue gradually increased, muscle tissue dissolved and inflammatory cell infiltration was not obvious at 24, 48, and 72 hours in experimental group; in control group, the gradual dissolution of muscle fibers and inflammatory cell infiltration were observed at 5, 24, and 48 hours, muscle tissue became swell ing, dissolving and degeneration and a large number of inflammatory cell infiltration gathered into the bacteria group at 72 hours. There was no significant difference in the number of bacteria per gram of tissue (P gt; 0.05) between experimental group and control group at 0 hour after injury; the numbers of bacteria in control group were significantly higher than those in experimental group at 12, 24, 48, and 72 hours (P lt; 0.05). Conclusion MRI combined with pathology show diagnostic meaning in treatment of gunshot wound with VSD. MRI can accurately reflect the scope of l imb gunshot wound 72 hours after injury. VSD may be an approach to delay infective time, shorten wound heal ing time, and promote the growth of healthy granulation tissue.
Objective To investigate the changes of transforming growth factor β1 (TGF- β1) and type Ⅱ of TGF-β-receptor (TβRⅡ) expressions in wound tissue after the treatment of diabetic foot with vaccum sealing drainage (VSD), and to analyze the mechanism of accelerating wound healing. Methods Between May 2012 and May 2016, 80 patients with diabetic foot were randomly divided into 2 groups, 40 cases in each group. After the same basic treatment, the wounds of VSD group and control group were treated with VSD and external dressing, respectively. There was no significant difference in gender, age, disease duration, body mass, foot ulcer area, and Wagner grade between 2 groups (P>0.05). The time of foundation preparation and hospitalization stay of 2 groups were recorded. The wound tissue was collected before treatment and at 7 days after treatment, and the positive indexes of TGF-β1 and TβRⅡexpressions were measured by immunohistochemical staining. Results Before skin grafting, the patients in VSD group were treated with VSD for 1 to 3 times (mean, 2 times), and the patients in control group were treated with dressing change for 1 to 6 times (mean, 4 times). The time of foundation preparation and hospitalization stay in VSD group were significantly shorter than those in control group (t=–13.546, P=0.036; t=–12.831, P=0.041). The skin grafts of both groups survived smoothly and the wound healed well. Before treatment, immunohistochemical staining results showed that the positive indexes of TGF-β1 and TβRⅡ expressions in VSD group were 5.3±2.4 and 14.0±2.6, while those in control group were 4.4±2.3 and 14.7±3.1, respectively. There was no significant difference between 2 groups (t=1.137, P=0.263; t=1.231, P=0.409). At 7 days after treatment, the positive indexes of TGF-β1 and TβRⅡ expressions in VSD group were 34.3±2.9 and 41.7±3.7, respectively, and those in control group were 5.8±2.0 and 18.1±2.5. There were significant differences between 2 groups (t=–35.615, P=0.003; t=23.725, P=0.002). Conclusion VSD can increase the expressions of TGF-β1 and TβRⅡ in diabetic ulcer tissue, promote granulation tissue growth, and accelerate wound healing.
ObjectiveTo explore the effectiveness of vacuum sealing drainage (VSD) combined with open bone graft for tibial traumatic osteomyelitis. MethodsBetween June 2007 and December 2012, 23 cases of tibial traumatic osteomyelitis were treated, including 15 males and 8 females with an average age of 32.5 years (range, 22-48 years). The time from injury to admission was 7-18 months (mean, 8.6 months). There was local bone scarring in 15 cases, the size ranged from 8 cm×4 cm to 15 cm×8 cm. The CT multi-planar reconstruction was carried out preoperatively. Eleven cases had segmental bone sclerosis with a length of 1.5 to 3.8 cm (mean, 2.6 cm); 12 cases had partial bone sclerosis with a range of 1/3 to 2/3 of the bone diameter. On the basis of complete debridement, infection was controlled by VSD; bone defect was repaired by VSD combined with open bone graft. After there was fresh granulation tissue, the wound was repaired by free skin graft or local skin flap transfer. ResultsNail infection occurred in 2 cases, which was cured after the use of antibiotics. The wound healed at the first stage after repairing. All cases were followed up 10-18 months (mean, 13.5 months). In 11 cases of segmental bone sclerosis, the infection control time was 7-14 days (mean, 8.8 days); the bone healing time was 32-40 weeks (mean, 34.4 weeks); and the frequency of VSD was 3-6 times (mean, 4.5 times). In 12 cases of partial bone sclerosis, the infection control time was 7-12 days (mean, 8.3 days); the bone healing time was 24-31 weeks (mean, 27.3 weeks); and the frequency of VSD was 3-5 times (mean, 3.6 times). Infection recurred in 1 case, and the patient gave up the therapy. No infection recurrence was observed in the other patients. ConclusionThe VSD combined with open bone graft is an effective method for the treatment of tibial traumatic osteomyelitis.