Luo Xu, Xin Guo-hua, Zeng Tao-fang, Lin Cai, Zeng Yuan-lin, Li Yu-cong, Qiu Ze-liang
Center of Wounds and Burns of the First Affiliated Hospital of Wenzhou Medical University, Wenzhou 325000, China.
Center of Wounds and Burns of the First Affiliated Hospital of Wenzhou Medical University, Wenzhou 325000, China. Email:
Zhonghua Shao Shang Za Zhi. 2013 Dec;29(6):541-7.
To observe the effects of microporous porcine acellular dermal matrix (ADM) combined with bone marrow mesenchymal cells (BMMCs) population containing bone mesenchymal stem cells (BMSCs) of rats on the regeneration of cutaneous appendages cells in nude mice.
Split-thickness dermal grafts, 20 cm×10 cm in size and 0.3 mm in thickness, were prepared from a healthy pig which was sacrificed under sanitary condition. Laser microporous porcine ADM (LPADM) was produced by laser punching, hypertonic saline solution acellular method, and crosslinking treatment, and nonporous porcine ADM (NPADM) was produced by the latter two procedures. Then the appearance observation, histological examination and scanning electron microscope observation were conducted. BMMCs were isolated and cultured from tibia and femur after sacrifice of an SD rat. Osteogenic and adipogenic differentiation experiments were conducted among the adherent cells in the third passage. Then they were inoculated to LPADM and NPADM to construct BMMCs-LPADM and BMMCs-NPADM materials. Twenty-one healthy nude mice were divided into BMMCs-LPADM+NPADM group (A, n = 6), LPADM+split-thickness skin graft group (B, n = 6), BMMCs-LPADM+split-thickness skin graft group (C, n = 6), BMMCs-NPADM+split-thickness skin graft group (D, n= 3) according to randomized block. After anesthesia, a 2 cm×2 cm full-thickness skin defect reaching deep fascia was reproduced in the middle of the back of each nude mouse, and a split-thickness skin graft of the same size was obtained, and then prepared skin grafts were transplanted to cover the wounds respectively. On post transplantation day (PTD) 5, 7, and 14, local condition and adverse effects observation was conducted; one nude mouse was sacrificed each time to harvest all the transplant for tissue structure observation with HE staining. On PTD 7 and 14, neonatal skin appendages in corresponding composite materials were observed with transmission electron microscope.
(1) LPADM and NPADM appeared to be porcelain white, soft, and flexible. No cellular component was observed in acellular dermal matrix. Scanning electron microscope showed that the collagen fibers were orderly arranged. LPADM had microporous structure. (2) Cells in the third passage were orderly arranged with the shape similar to fibroblasts with high growth speed. (3) Induced differentiation experiments showed that cells could differentiate into osteoblasts and adipocytes. (4) On PTD 5, the NPADM in group A was dry in part; skin grafts in group D were dry and necrotic, and there was no infection and inflammation in groups A and D; skin grafts in groups B and C survived. On PTD 7 and 14, the overlaying material in group A was black, dry, and hard in part; the skin grafts in group D turned to be completely black, dry, and necrotic, and pale yellow clear exudate was found in subcutaneous area; there was no obvious purulent discharge in groups A and D; the appearance of skin grafts in groups B and C was close to the surrounding skin. (5) On PTD 5 and 7, in groups A, B, and C, vascularization was apparent in the pores of dermal matrix, and red blood cells could be found. In group D, skin grafts were dry and necrotic. On PTD 14, in groups A, B, and C, the pore structure of dermal matrix was fully vascularized in which a large number of red blood cells were visible. In group A, the microporous dermal matrix survived, but the overlaying NPADM was not attached closely. In groups B and C, the skin grafts were closely connected to the dermal matrix, and no cutaneous appendages were observed. In group C, special monolayer cells were found at the junction between skin graft and dermal matrix. (6) Skin grafts in group D failed to survive; they were not observed with the electron microscope. On PTD 7, there were no significant differences among groups A, B, and C. On PTD 14, no sebaceous gland-like cell or sweat gland-like cell and no newborn nerve ending were observed in skin grafts in groups A and B, in spite of the immigration of fibroblasts. In group C, a large number of new capillaries were observed at the junction between the skin graft and dermal matrix; rough endoplasmic reticulum of fibroblasts proliferated exuberantly; newborn unmyelinated nerve endings were observed; single free sweat gland-like cells and sebaceous gland-like cells were observed in superficial dermal matrix.
LPADM, which provides a "cell niche-like" micro-environment for the migration and differentiation of the BMMCs population, when combining with the split-thickness skin graft, can induce exogenous differentiation of BMSCs in vivo, thus achieving the reconstruction of skin appendages.
观察微孔猪脱细胞真皮基质(ADM)联合含大鼠骨髓间充质干细胞(BMSCs)的骨髓间充质细胞(BMMCs)对裸鼠皮肤附属器细胞再生的影响。
在卫生条件下处死健康猪,制备大小为20 cm×10 cm、厚度为0.3 mm的中厚皮片。采用激光打孔、高渗盐溶液脱细胞法及交联处理制备激光微孔猪ADM(LPADM),后两种方法制备无孔猪ADM(NPADM)。然后进行外观观察、组织学检查和扫描电子显微镜观察。SD大鼠处死后,从胫骨和股骨分离培养BMMCs。对第三代贴壁细胞进行成骨和成脂分化实验。然后将它们接种到LPADM和NPADM上构建BMMCs-LPADM和BMMCs-NPADM材料。将21只健康裸鼠按随机区组法分为BMMCs-LPADM+NPADM组(A组,n = 6)、LPADM+中厚皮片移植组(B组,n = 6)、BMMCs-LPADM+中厚皮片移植组(C组,n = 6)、BMMCs-NPADM+中厚皮片移植组(D组,n = 3)。麻醉后,在每只裸鼠背部正中制作一个2 cm×2 cm深达深筋膜的全层皮肤缺损,获取同样大小的中厚皮片,然后将制备好的皮片分别移植覆盖创面。在移植后第5、7和14天,观察局部情况及不良反应;每次处死1只裸鼠,取所有移植组织进行HE染色观察组织结构。在移植后第7和14天,用透射电子显微镜观察相应复合材料中的新生皮肤附属器。
(1)LPADM和NPADM呈瓷白色,柔软且有弹性。脱细胞真皮基质中未观察到细胞成分。扫描电子显微镜显示胶原纤维排列有序。LPADM具有微孔结构。(2)第三代细胞排列有序,形态与成纤维细胞相似,生长速度快。(3)诱导分化实验表明细胞可分化为成骨细胞和脂肪细胞。(4)移植后第5天,A组的NPADM部分干燥;D组的皮片干燥坏死,A组和D组均无感染和炎症;B组和C组的皮片存活。移植后第7和14天,A组的覆盖材料部分呈黑色、干燥且坚硬;D组的皮片完全变黑、干燥坏死,皮下有淡黄色清亮渗出物;A组和D组无明显脓性分泌物;B组和C组皮片外观接近周围皮肤。(5)移植后第5和7天,A、B、C组真皮基质孔隙内血管化明显,可见红细胞。D组皮片干燥坏死。移植后第14天,A、B、C组真皮基质孔隙结构完全血管化,可见大量红细胞。A组微孔真皮基质存活,但覆盖的NPADM贴附不紧密。B组和C组皮片与真皮基质紧密相连,未观察到皮肤附属器。C组在皮片与真皮基质交界处发现特殊的单层细胞。(6)D组皮片未能存活,未进行电子显微镜观察。移植后第7天,A、B、C组之间无显著差异。移植后第14天,A组和B组皮片中虽有成纤维细胞迁入,但未观察到皮脂腺样细胞或汗腺样细胞,也未观察到新生神经末梢。C组在皮片与真皮基质交界处观察到大量新生毛细血管;成纤维细胞粗面内质网增生旺盛;观察到新生无髓神经末梢;在真皮浅层观察到单个游离的汗腺样细胞和皮脂腺样细胞。
LPADM为BMMCs群体的迁移和分化提供了“类细胞龛”微环境,与中厚皮片联合时,可诱导体内BMSCs的外源性分化,从而实现皮肤附属器的重建。
