目的:了解大鼠脑出血后血肿周围组织细胞凋亡与神经元特异性烯醇化酶(NSE)的表达及大鼠神经功能缺损程度的关系。方法:用胶原酶注入到大鼠尾状核的方法制作脑出血模型。将大鼠分为脑出血、假手术组、正常组3组。采用苏木素伊红(HE) 染色、NSE免疫组织化学染色及TUNEL分别观察各组在脑出血后第6 h、12 h、24 h、48 h、72 h、5 d、7 d时血肿周围NSE及TUNEL的表达。用Longa评分法评价大鼠神经功能缺损程度。结果:大鼠在胶原酶注入6 h后形成稳定的血肿,在造模24~48 h神经功能缺损程度最重;6 h即见到TUNEL阳性细胞的表达,在48 h最明显;NSE从神经元中漏出弥散到细胞间隙也在48 h达高峰。结论:脑出血血肿周围凋亡与神经功能缺损及NSE的变化有关,凋亡可能在脑出血的神经损伤中起重要的作用。
Objective To observe the clinical outcome of primary repair of the tissue defects of the Achilles tendon and skin by thigh anterolateral free flap and free iliotibial tract. Methods From January 2000 to January 2005, the thigh anterolateral free flap and the iliotibial tract were used to primarily repair the defects of the Achilles tendon and skin in 11 patients (7 males and 4 females, aged 6-45 years). The defects of the skin and Achilles tendon were found in 6 patients, and the defects of the Achilles tendonand skin accompanied by the fracture of the calcaneus were found in 5 patients.The defect of the Achilles skin was 6 cm×5cm-14 cm×8 cm in area. The defect of the Achilles tendon was 511 cm in lenth. The skin flap was 11 cm×6 cm-17 cm×11 cm in area.The iliotibial tract was 7-13 cm in length and 3-5 cm in width. The medial and lateral borders were sutured to from double layers for Achilles tendon reconstruction. The woundon the donor site could be sutured directly in 5 patients, and the others could be repaired with skin grafting. Results After operation, all the flaps survived and the wound healed by first intention. The followup of the 11 patients for 6 mouths-4 years (average, 30 months) revealed that according to Yin Qingshui’s scale, the result was excellent in 6 patients, goodin 4, and fair in 1. The excellent and good rate was 99%. The results showed a significant improvement in the “heel test” and the Thompson sign, and both were negative. No complications of ulceration on the heel and re-rupture of the Achiles tendon occurred. Conclusion The primary repair of the tissue defects of the Achilles tendon and skin by free grafting of the anterolateral femoral skin flap and the iliotibial tract is an effective surgical method.
Objective To introduce the surgical procedure and indication of the reverse fascial pedicle island flap of the digital artery dorsal branches in repairing finger skin defect. Methods By use of the dorsal branches of the digital artery as the pedicel, the reverse island flap was designed. The skin defectsof the proximal interphalangeal joint and beyond in 35 cases (42 fingers) were repaired and the joint or extensor tendon was reconstructed simultaneously. Donor site was primarily closed or a skin graft was used. The flap size ranged from 1.0 cm×2.5 cm to 1.5 cm×3.5 cm.Results Thirtyfive patients were followed up 3 months to 1 year, all the flaps survived. The two-point discrimination was between 6 mm and 10 mm. The function of interphalangeal joint was satisfactory.Conclusion These flaps have the advantages of an extended skinpaddle and a versatile pivot point on the phalanx, and they allow coverage of wide and distal defects.
Objective To observe the ability to repair bilateralradius bone defect with the composite of β-tricalciumphosphate(βTCP),hyaluronic acid(HA),type I collagen(COL-Ⅰ) and induced marrow stromal cells(MSCs), and to investigate the feasibility of the composite as a bone substitute material.Methods The MSCs of the New Zealand white rabbits were induced into ostoblasts, then combined with β-TCP, HA and COL-Ⅰ. Thirty New Zealand white rabbits were made the bilateral radius bone defects of 2 cm and divided into groups A, B and C. After 8 weeks, β-TCP-HA-COL-Ⅰ-MSCs (group A, n=27 sides), autograft (group B, n=27 sides)andno implant(group C as control, n=6 sides)were implanted into the areas ofbilateral radius bone defects, respectively. The structure of the composite was observed by scanning electron microscope. The repairing effect was observed by gross, histomorphology, X-ray examination, and the degradation rate of inorganic substance at 4, 8 and 12 weeks. The ostogenic area and biomechanics ofgroup A were compared with those of group B at 12 weeks.Results The MSCs could stably grow in vitro, relatively rapidly proliferated, and could be induced into the ostoblasts.The composite was porous. The results of gross, histomorphology and X-ray showed that the bone defects were perfectly repaired in group A and group B, but not in group C. The ostogenic area or biomechanics had no statistically significant difference between groups A and B(Pgt;0.05). The weight of inorganic substance in group A were 75% ,57% and 42% at 4,8,12 weeks, respectively.Conclusion MSCs can be used as seedcells in the bone tissue engineering. The composite has porous structure, no reactions of toxicity to the tissue and rapid degradation, and it is an ideal carrier of seed cells.The β-TCP-HA-COL-Ⅰ-MSCs composite has the high ability of repairing bone defect and can serve as an autograft substitute material.
Objective To investigate the effect of “two-phase” tissue engineered cartilage constructed by autologous marrow mesenchymal stem cells(MSCs) and allogeneic bone matrix gelatin(BMG) in repairing articular cartilage defects. Methods Thirty-twoNew Zealand white rabbits were involved in the experiment. “Two-phase” allogeneic BMG scaffold (one side of porous cancellous bone and the other side of cortical bone; 3 mm both in diameter and in thickness) was prepared from iliac bone and limb bone of 5 rabbits by sequentially chemical method. The MSCs wereseparated from 18 New Zealand white rabbits and induced to express chondrocyticphenotype. The chondrocyte precursor cells were seeded onto “two-phase” allogeneic BMG to construct tissue engineering cartilage. Masson’s trichrome staining, PAS staining and scanning electronic microscopic observation were carried out at 1, 3 and 5 weeks. The defects of full thickness articular cartilage(3 mm both in diameter and in depth) were made at both sides of femoral medial condyles in 27 rabbits(including 18 of separated MSCs and the remaining 9). The defects were repaired with the tissue engineered cartilage at the right side (group A, n=18), with BMG at the left side(group B, n=18), and without any implant at both sides in the remaining 9 rabbits as a control( group C, n=18). After 1, 3 and6 months, the 6 specimens of femoral condyles were harvested in 3 groups, respectively. Gross observation, Masson’s trichrome and Alcian blue staining, modified Wakitani scoring and in situ hybridization of collagen type Ⅱ were carried out to assess the repair efficacy of tissue engineered cartilage. Results The “two-phase” BMG consisted of the dense cortical part and the loose cancellous part. In cancellous part, the pore size ranged 100-800 μm, in which the chondrocyte precursor cells being induced from MSCs proliferated and formed the cell-rich cartilaginous part of tissue engineered cartilage. In cortical part, the pore size ranged 10-40 μm, on which the cells arranged in a layer and formed the hard part of subchondral bone. After 1 month of transplantation, the cartilage and subchondral bone were regenerated in group A; during observation, the regenerated cartilage graduallythinned, but defect was repaired and the structure of the articular surface ansubchondral bone was in integrity. In groups B and C, defects were not repaired, the surrounding cartilage of defect was abrased. According to the modified Wakitani scoring, the indexes in group A were significantly higher than those in group B and C(Plt;0.01) except the thickness of cartilage at 6 months. The positive cell rate of in situ hybridization for collagen type Ⅱ in group A was also higher than those in groups B and C(Plt;0.01). Conclusion “Two-phase” allogeneic BMG is a prospective scaffold for tissue engineered cartilage,which combines with autologous chondrocyte precursor cells induced from MSCs toconstruct the tissue engineering cartilage. The tissue engineered cartilage can repair defects of articular cartilage and subchondral bone.