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Under the vigorous support of the Chinese Burn Association, MEEK skin-grafting technique has accumulated abundant experiences during widespread clinical application in burn surgery in a long term, since its import into China over a decade ago. Recently, it has been widely and successfully used in many big rescues of burn casualties. In order to obtain more better gasp on MEEK skin-grafting technique and play its advantage, MEEK Micro-skin Transplantation Technology Collaboration Group of Chinese Burn Association organized domestic experts to complie clinical operation procedure of grafting technique of MEEK micro-skin, including indication, preoperative preparation, operating procedure, postoperative care, and points for attention, for getting more standard application of this technology and better therapeutic outcome.
Subject(s)
Humans , Burns , General Surgery , China , Postoperative Care , Skin , Skin Transplantation , MethodsABSTRACT
Under the vigorous support of the Chinese Burn Association, MEEK skin-grafting technique has accumulated abundant experiences during widespread clinical application in burn surgery in a long term, since its import into China over a decade ago. Recently, it has been widely and successfully used in many big rescues of burn casualties. In order to obtain more better gasp on MEEK skin-grafting technique and play its advantage, MEEK Micro-skin Transplantation Technology Collaboration Group of Chinese Burn Association organized domestic experts to complie clinical operation procedure of grafting technique of MEEK micro-skin, including indication, preoperative preparation, operating procedure, postoperative care, and points for attention, for getting more standard application of this technology and better therapeutic outcome.
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Objective@#To analyze the reasons for failure of Meek micro-skin grafting in children with severe burns and to observe the clinical effects of the treatment measures.@*Methods@#Thirty children with severe burns hospitalized in the First Affiliated Hospital of Anhui Medical University (hereinafter referred to as the author′s affiliation) from January 2012 to January 2018, conforming to the inclusion criteria were included to failed skin graft group. Children in failed skin graft group were performed with Meek micro-skin grafting operation and the operation failed, including 17 males and 13 females aged 1 to 12 year(s). Thirty children with severe burns hospitalized in the author′s affiliation during the same period of time, conforming to the inclusion criteria, were included to successful skin graft group. Children in successful skin graft group were performed with Meek micro-skin grafting operation and the operation succeeded, including 16 males and 14 females aged 1 to 12 year(s). Main treatment measures and effects before operation, area and survival rate of Meek micro-skin graft, infected pathogens status, selection status of sensitive antibiotics, preoperative nutrition status, and wound infection status in plum rain season of children in the two groups, and nutritional status before and after strengthening nutritional support of postoperative surviving children in failed skin graft group were analyzed retrospectively. Data were processed with chi-square test and t test.@*Results@#(1) The numbers of children in the two groups performed with main treatment measures of dilatation and anti-shock, tracheotomy intubation, ventilator-assisted respiration, and limb incision decompression after admission were close (χ2=0, 0.016, 0.025, 0.009, P>0.05). After taking the above-mentioned main treatment measures, effects of correcting shock, preventing asphyxia, correcting breathing difficulty, and improving peripheral circulation of limb were achieved. (2) The area of Meek micro-skin grafting of children in successful skin graft group was (20.6±2.5)% total body surface area (TBSA), close to (21.2±2.2)% TBSA in failed skin graft group (t=0.534, P>0.05). The survival rate of Meek micro-skin graft of children in successful skin graft group was (79±5)%, significantly higher than (26±3)% in failed skin graft group (t=2.956, P<0.01). (3) The microbial culture of wound secretion of 5 (16.67%) children in 30 patients in successful skin graft group was positive, with Pseudomonas aeruginosa of 2 children, and Escherichia coli, Staphylococcus aureus, and Aspergillus of one patient respectively. As children in successful skin graft group were with no symptom of systemic infection, no blood microbial culture was done. The microbial culture of wound secretion of 30 (100.00%) children in 30 patients in failed skin graft group was positive, and blood microbial culture of 8 (26.67%) children was positive. The main pathogen was Pseudomonas aeruginosa of 11 (36.67%) children in 8 pathogens caused infection with gram-negative bacteria of 22 (73.33%), gram-positive bacteria of 11 (36.67%) children, and fungi of 6 (20.00%) children. (4) Ten kinds of sensitive antibiotics such as cephalosporins, glycopeptides, carbapenems, and tetracyclines antibiotics were used in children in failed skin graft group, of which the use rate of imipenem of 9 (30.00%) was the highest. Only 4 kinds of sensitive antibiotics such as ceftazidime were used in 30 children in successful skin graft group. (5) The preoperative levels of albumin and prealbumin of children in successful skin graft group were (32±4) g/L and (133±41) mg/L respectively, significantly higher than (27±4) g/L and (93±35) mg/L in failed skin graft group (t=5.090, 4.064, P<0.01). The albumin and prealbumin levels of postoperative surviving children in failed skin graft group after nutritional support treatment were (35±4) g/L and (168±49) mg/L, significantly higher than (27±4) g/L and (94±38) mg/L before nutritional support treatment (t=6.911, 6.315, P<0.01). (6) Wound infection of 9 children in 30 children with wound infection in failed skin graft group happened in the plum rain season, and fungi infection of 3 children in 6 children with fungi infection happened in the plum rain season. Wound infection of 2 children in 5 children with wound infection in successful skin graft group happened in the plum rain season, and the only one children with fungi infection happened in the plum rain season.@*Conclusions@#The main reasons for the failure of Meek micro-skin grafting in children with severe burns include infection, nutrition, and season factors, etc. Measures of strengthening wound dressing change, reasonable use of sensitive antibiotics to control infection, internal and external intestinal nutritional support, and reducing disturbance of the plum rain season by enhancing ventilation are effective and worthy of clinical promotion.
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Objective@#To establish a method for repairing extremities with extensively deep burn using large piece of fresh allogeneic scalp spliced by Meek glue combined with autologous microskin and observe its effect.@*Methods@#Medical records of two male patients with extremely extensive deep burn admitted to our hospital from May to November in 2018 were retrospectively analyzed. Two patients aged 44 and 25 years respectively, with total burn area of 90% and 97% total body surface area (TBSA) and full-thickness burn area of 85% and 70% TBSA, respectively. Preoperatively, the surgical area on the extremities was calculated to estimate the necessary amount of allogeneic scalp and Meek miniature skin. The large piece of fresh allogeneic scalp spliced by Meek glue combined with autologous microskin was prepared according to the methods described as follows. Thin medium-thickness fresh scalps with 3% TBSA and 0.30-0.35 mm in depth were harvested from each donor and spliced into a large piece with epidermis upward by spraying Meek glue. Then the spliced scalp was punched after covered with a single-layer gauze. Autologous microskin was transported onto the dermis of fresh large piece of allogeneic scalp by traditional floating method. Bilateral extremities with full-thickness burn of two patients were selected for self-control. The left upper extremity was denoted as treatment group while the right upper extremity was denoted as control group in Patient 1. The right lower extremity was denoted as treatment group while the left lower extremity was denoted as control group in Patient 2. Wounds in the treatment group were treated with fresh large piece of allogeneic scalp spliced by Meek glue and autologous microskin with expansion ratio of 1∶15 after escharectomy, while wounds in control group received grafting of Meek miniature skin with expansion ratio of 1∶6 and or 1∶9 after escharectomy. The donors of allogeneic scalp were 32 males who were the relatives or friends of the patients, aged 21-50 years, with scalp area of (548±48) cm2. The healing conditions of donor sites of scalp were observed on post operation day 10, and were followed up within 3 months after operation to observe whether forming alopecia and hypertrophic scar or not. Wound healing condition was evaluated during follow-up in post operation week (POW) 2-5 and 4 months after operation. Wound coverage rates were calculated in both treatment and control groups in POW 2, 3, 4, and 5.@*Results@#The donor sites of all allogeneic scalp of donors healed completely on post operation day 10. There was no alopecia or hypertrophic scar within 3 months after operation for follow-up. In POW 2, allogeneic scalp grafts basically survived in treatment group without obvious exudation, and most of the Meek miniature skin survived in control group with obvious exudation. Part of allogeneic scalp grafts dissolved and detached in treatment group in POW 3, and the surviving grafts scabbed. The eschar detached and new epithelium was observed in treatment group in POW 4 and 5. In POW 3-5, surviving Meek miniature skin in control group creeped and was incorporated, and the wounds shrank. Hypertrophic scar was observed in both treatment and control groups 4 months after operation, without obvious difference in scar as a whole. The wound coverage rates were respectively 84%-98% and 76%-92% in treatment group of two patients in POW 2-5, close to or higher than those of control group (35%-97% and 28%-81%, respectively).@*Conclusions@#The study establishes a novel method for splicing fresh allogeneic scalps into a large piece as the covering of microskin, which has good effect for repairing extensively deep burn wounds. Considering that allogeneic skin is scarce, this method may be a new option in clinical treatment for extensively deep burn patients.
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Objective To explore the promoting effects of bio-polymer composite film as a micro-skin auto-graft covering on wound healing. Methods The full thickness skin defect models were made on both sides of 30 experimental rabbits. Then, the rabbits were randomly divided into experimental group and control group. In the for-mer group, the side was covered with chitosan/glucomannan composite membrane and in the latter, the side cov-ered with acelluar porcine skin after micro-skin autograft. We obtained wound tissues at week 1 , 2, 3, 4 and 5 af-ter operation. The conditions of wound healing were observed, the rate of wound healing was calculated, HE stain-ing was made, and PCNA and CD31 were detected by immunohistochemistry. Results (1) During 2~4 weeks af-ter operation, the rate of wound healing in the experimental group was significantly higher than that of the control wound (P<0.01). (2) The amount of neutrophil in experimental group was less than that of the control after oper-ation. (3) During 1 ~ 2 weeks after operation, the expression of PCNA in the experimental group was higher than that of the control group (P < 0.01), but lower than the control wounds during 1 ~ 2 weeks after operation (P <0.01). (4) During 1 ~ 5 weeks after operation, the expression of CD31 in the experimental group was higher than that of the control group (P < 0.01). Conclusion Chitosan/glucan-mannan composite membrane as a micro-skin autograft covering may promote wound healing.
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Objective To investigate the effect of mixed-skin grafting with autologous microskin and allogenetic acellular dermal matrix microskin on wound healing in rats,and to make a further study on the related mechanism.Methods Wistar rats were served as a allogenetic acellular dermal matrix donor rats,and SD rats as acceptors with mould of full thickness skin defects on their back.The ninety SD rats were divided into 5 groups with 18 rats in each group.Group 1 was transplanted with autologous microskin,and group 2 with allogenetic acellular dermal matrix microskin.Groups 3,4 and 5 were grafted with mixed-skin ratio between autologous microskin and allogenetic acellular dermal matrix microskin 1 ∶ 1,1 ∶ 0.5 and 1 ∶ 0.25,repectively.The rate of wound healing was measured,wound samples collected,hematoxylin and eosin stain carried out,fibronectin (FN) and laminin (LN)detected,and intergroup comparison made,respectively,2,3 and 4 weeks after skin grafting.Results The wound healing rates and FN and LN expression of mixed-skin grafting groups were higher than those of the group with autologous microskin grafting.The group of 1 ∶ 0.25 obviously increased (P<0.05 or P<0.01).Conclusions The wound healing rate with mixed-skin grafting is higher than that with autologous microskin grafting.The best effect is achieved when the skin ratio between autologous microskin and allogenetic acellular dermal matrix microskin is 1 ∶ 0.25.It is possibly due to the increase of FN and LN on wound skin surface.
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Objective: To evaluate the advantages of microskin graft using acellular porcine skin for treatment of extensive deep burns by comparing with that using allogeneic skin. Methods: A retrospective analysis was conducted on 70 severe burn patients who were treated in the Second Affiliated Hospital of Kunming Medical University during Jan. 1999 to Jan. 2011. The patients were divided into the acellular porcine skin group and allogeneic skin group, each containing 35 patients. The survival rates of microskin grafts were determined at 4 weeks post-operation. Besides, the rejection of acellular porcine skin and allogeneic skin, changes of body temperature, white blood cell (WBC) count, lymphocyte and serum protein were observed at pre- and post-operation. Results: (1) The survival rate was (71. 5 ± 6. 6)% in acellular porcine skin group and (70. 6 ± 7. 5)% in allogeneic skin group, with no significant difference found between the two groups (P>0. 05). (2) Acellular porcine skin group. At 3 days post-operation the acellular porcine skin was still attached to the wound, most of the skin was not discolorated, and small part of the skin became cinnamomeous. The acellular porcine skin was gradually separated from the auto-microskin at 3-4 weeks post operation, and there was small amount of exudates under the acellular porcine skin, which could be drained through a small cut. In the pressed area, there was still a small amount of exudates, but the acellular porcine skin was not dissolved and the microskin grafts survived and became confluent. (3) Allogeneic skin group. The allogeneic epidermal was rejected and was off from the wound at 3-14 days post transplantation, and at 10-30 days after transplantation the allogenic dermis became dry. During 25-60 days after transplantation, the allogenic dermis was completely stripped off, the microskin grafts became confluent, and the wound was healed. (4) The body temperature of the two groups was significantly descended after operation (P0. 05). Conclusion: Microskin graft using acellular porcine skin, instead of allogeneic skin, for extensive burn patients can inhibit systematic inflammatory response, improve the nutrition condition, and reduce the using of allogeneic skin. Acellular porcine skin might be a suitable alternative for allogeneic skin.
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Microskin autografts were covered with artificial collagen skin, pig skin and cadaver skin in the rats. The results showed that the adhesion to wound and hemostasis of artificial collagen skin was better than pig or cadaver skins. The histological section of healing wound with artificial collagen skin showed that there were revascularization and fibroblast infiltration. The results suggest that artificial collagen skin may be used instead of allograft.