精准分层缝合联合壳聚糖医用生物凝胶对急诊面部外伤患儿伤口愈合的影响

目的:探讨精准分层缝合联合壳聚糖医用生物凝胶对急诊面部外伤患儿伤口愈合的影响。方法:选取2021年1月-2022年1月笔者医院整形外科急诊收治的面部外伤患儿90例,按随机数字表法分为对照组和联合组,各45例。两组患儿均给予精准分层缝合,在此基础上,联合组每日换药后在伤口处涂抹壳聚糖医用生物凝胶。观察比较两组患儿伤口愈合情况、温哥华瘢痕量表(Vancouver scar scale,VSS)评分、石溪瘢痕量表(Stony brook scar evaluation scale,SBSES)评分、美观满意度评分及不良反应。结果:联合组患儿伤口愈合时间短于对照组(P<0.05);术后3个月,联合组患儿伤口愈合优良率高于对照组,VSS评分低于对照组,SBSES评分、面部美观满意度评分高于对照组,以上指标组间比较差异均有统计学意义(P<0.05);术后,联合组不良反应总发生率低于对照组(P<0.05)。结论:采用精准分层缝合联合壳聚糖医用生物凝胶治疗急诊面部外伤患儿,能促进患儿伤口愈合,减少瘢痕形成,提高美观满意度,且不良反应发生率低。

精准分层缝合配合医用生物凝胶对急诊面部外伤患儿疤痕情况及满意度的影响

目的探究急诊面部外伤患儿采用精准分层缝合联合医用生物凝胶治疗的临床疗效。方法选取长沙市第四医院接收的80例急诊面部外伤患儿为研究对象,依据随机数字表法分组(对照组:采用精准分层缝合术,观察组:采用精准分层缝合术+医用生物凝胶),每组40例,对比各组瘢痕美容评估与评级量表(SCAR)评分、伤口愈合情况、并发症发生率、面部美观满意度。结果两组治疗后3个月、6个月SCAR评分对比,观察组更低,数据对比有统计学意义(P<0.05);对照组与观察组治疗后愈合优良患者分别为28例、37例,优良率分别为70.00%、92.50%,数据对比有统计学意义(P<0.05);两组治疗后并发症发生率对比,观察组更低,数据对比有统计学意义(P<0.05);与对照组相比,观察组治疗后满意度评分更高,数据对比有统计学意义(P<0.05)。结论面部外伤因发病急,在急诊治疗时采用精准分层缝合联合医用生物凝胶治疗,可显著减少瘢痕形成,患者满意度高,值得推广。

医用生物蛋白凝胶预防腰椎间盘突出症术后瘢痕粘连的临床应用

目的观察医用生物蛋白凝胶预防腰椎间盘突出症术后瘢痕粘连的临床效果。方法回顾性分析自2014-01—2016-02采用半椎扳切除或开窗减压椎间盘摘除术治疗的64例腰椎间盘突出症,观察组36例术中在硬膜囊及神经根周围加入生物蛋白凝胶,对照组28例未使用生物蛋白凝胶。结果 64例均获得随访,随访时间平均26(12~40)个月。观察组术后2例(5.6%)出现下腰痛,对照组5例(17.9%)出现下腰痛;观察组术后下腰痛发生率低于对照组,差异有统计学意义(P<0.05)。末次随访时JOA评分:观察组优27例,良7例,可2例;对照组优15例,良5例,可3例,差5例;观察组末次随访时JOA评分优于对照组,差异有统计学意义(P<0.05)。结论医用生物蛋白凝胶可作为腰椎间盘突出症半椎扳切除或开窗减压椎间盘摘除术中常规预防硬膜外瘢痕粘连的辅助材料。

Designing the mechanical properties of peptide-based supramolecular hydrogels for biomedical applications

Hydrogels are a class of special materials that contain a large amount of water and behave like rubber.These materials have found broad applications in tissue engineering,cell culturing,regenerative medicine etc.Recently,the exploration of peptide-based supramolecular hydrogels has greatly expanded the repertoire of hydrogels suitable for biomedical applications.However,the mechanical properties of peptide-based hydrogels are intrinsically weak.Therefore,it is crucial to develop methods that can improve the mechanical stability of such peptide-based hydrogels.In this review,we explore the factors that determine or influence the mechanical stability of peptide-based hydrogels and summarize several key elements that may guide scientists to achieve mechanically improved hydrogels.In addition,we exemplified several methods that have been successfully developed to prepare hydrogels with enhanced mechanical stability.These mechanically strong peptide-based hydrogels may find broad applications as novel biomaterials.It is still challenging to engineer hydrogels in order to mimic the mechanical properties of biological tissues.More hydrogel materials with optimal mechanical properties suitable for various types of biological applications will be available in the near future.