Li Yashu, Liu Anqi, Wang Jingyan, Yang Changsheng, Lv Kaiyang, He Weifeng, Wu Jun, Chen Wenbin
Department of Plastic Surgery, Xinhua Hospital, Shanghai Jiao Tong University School of Medicine, No. 1665 Kangjiang Road, Yangpu District, Shanghai 200092, People's Republic of China.
Department of Dermatology, Xiangya Hospital, Central South University, Changsha, Hunan 410008, People's Republic of China.
Burns Trauma. 2024 Oct 20;12:tkae051. doi: 10.1093/burnst/tkae051. eCollection 2024.
Hypertrophic scars cause impaired skin appearance and function, seriously affecting physical and mental health. Due to medical ethics and clinical accessibility, the collection of human scar specimens is frequently restricted, and the establishment of scar experimental animal models for scientific research is urgently needed. The four most commonly used animal models of hypertrophic scars have the following drawbacks: the rabbit ear model takes a long time to construct; the immunodeficient mouse hypertrophic scar model necessitates careful feeding and experimental operations; female Duroc pigs are expensive to purchase and maintain, and their large size makes it difficult to produce a significant number of models; and mouse scar models that rely on tension require special skin stretch devices, which are often damaged and shed, resulting in unstable model establishment. Our group overcame the shortcomings of previous scar animal models and created a new mouse model of hypertrophic scarring induced by suture anchoring at the wound edge.
We utilized suture anchoring of incisional wounds to impose directional tension throughout the healing process, restrain wound contraction, and generate granulation tissue, thus inducing scar formation. Dorsal paired incisions were generated in mice, with wound edges on the upper back sutured to the rib cage and the wound edges on the lower back relaxed as a control. Macroscopic manifestation, microscopic histological analysis, mRNA sequencing, bioinformatics, and cell assays were also conducted to verify the reliability of this method.
Compared with those in relaxed controls, the fibrotic changes in stretched wounds were more profound. Histologically, the stretched scars were hypercellular, hypervascular, and hyperproliferative with disorganized extracellular matrix deposition, and displayed molecular hallmarks of hypertrophic fibrosis. In addition, the stretched scars exhibited transcriptional overlap with mechanically stretched scars, and human hypertrophic and keloid scars. Phosphatidylinositol 3-kinase-serine/threonine-protein kinase B signaling was implicated as a profibrotic mediator of apoptosis resistance under suture-induced tension.
This straightforward murine model successfully induces cardinal molecular and histological features of pathological hypertrophic scarring through localized suture tension to inhibit wound contraction. The model enables us to interrogate the mechanisms of tension-induced fibrosis and evaluate anti-scarring therapies.
增生性瘢痕会导致皮肤外观和功能受损,严重影响身心健康。由于医学伦理和临床可及性的原因,人体瘢痕标本的采集常常受到限制,因此迫切需要建立用于科研的瘢痕实验动物模型。四种最常用的增生性瘢痕动物模型存在以下缺点:兔耳模型构建时间长;免疫缺陷小鼠增生性瘢痕模型需要精心饲养和实验操作;雌性杜洛克猪购买和饲养成本高,且体型大,难以大量制备模型;依赖张力的小鼠瘢痕模型需要特殊的皮肤拉伸装置,该装置常损坏和脱落,导致模型建立不稳定。我们团队克服了以往瘢痕动物模型的缺点,创建了一种通过在伤口边缘缝合锚定诱导增生性瘢痕形成的新型小鼠模型。
我们利用缝合锚定切口伤口,在整个愈合过程中施加定向张力,抑制伤口收缩,并生成肉芽组织,从而诱导瘢痕形成。在小鼠背部制作成对切口,将上背部的伤口边缘缝合到肋骨上,下背部的伤口边缘放松作为对照。还进行了宏观表现、微观组织学分析、mRNA测序、生物信息学和细胞检测,以验证该方法的可靠性。
与放松对照组相比,拉伸伤口的纤维化变化更明显。组织学上,拉伸瘢痕细胞增多、血管增生、增殖活跃,细胞外基质沉积紊乱,并表现出肥厚性纤维化的分子特征。此外,拉伸瘢痕与机械拉伸瘢痕、人类增生性瘢痕和瘢痕疙瘩在转录上有重叠。磷脂酰肌醇3激酶-丝氨酸/苏氨酸蛋白激酶B信号通路被认为是缝合诱导张力下抗凋亡的促纤维化介质。
这种简单的小鼠模型通过局部缝合张力成功诱导了病理性增生性瘢痕的主要分子和组织学特征,以抑制伤口收缩。该模型使我们能够探究张力诱导纤维化的机制并评估抗瘢痕治疗方法。
