叙事护理在甲状腺全切除术患者中的应用效果

目的:分析叙事护理在甲状腺全切除术患者中的应用效果。方法:选择2022年1月—2024年2月在肇庆医学高等专科学校附属医院接受治疗的80例甲状腺全切除术患者作为研究对象,通过计算机随机数字软件生成数字1~80,双数为对照组,单数为观察组,各40例。对照组行常规护理,观察组行叙事护理。对比两组护理前后心理状态[焦虑自评量表(SAS)、抑郁自评量表(SDS)评分]及并发症发生率。结果:护理前,两组SAS、SDS评分比较,差异无统计学意义(P>0.05);护理后,两组SAS、SDS评分降低,观察组低于对照组(P<0.05)。观察组并发症发生率低于对照组(P=0.025)。结论:叙事护理可以进一步改善甲状腺全切除术患者的心理状态,减少并发症。

芋艿淀粉的功能特性

该文采用场发射扫描电子显微镜分析芋艿淀粉颗粒形态结构,采用快速黏度分析仪、差示扫描量热仪、流变仪分析淀粉糊化特征,采用体外酶解消化法分析淀粉消化特征。结果表明,温岭芋艿淀粉颗粒(3~5μm)明显大于奉化芋艿头和芋艿子淀粉颗粒(0.5~2μm),形状也较奉化芋艿淀粉规则,粒表面呈褶皱状并有裂纹;芋艿淀粉的糊化黏度参数数值均为温岭芋艿>奉化芋艿子>奉化芋艿头;温岭芋艿淀粉糊化峰值温度(80.3℃)显著低于奉化芋艿淀粉(83.3~84.3℃),但热晗值(18.3 J/g)则显著高于奉化芋艿淀粉(12.5~14.8 J/g),温岭芋艿回生淀粉糊化吸收热晗值(3.2 J/g)显著低于奉化芋艿(6.2~6.7 J/g);在低温和高频条件下,芋艿淀粉动态模量参数值相对较高,且芋艿淀粉动态模量参数值与直链淀粉含量大小有关,即:温岭芋艿>奉化芋艿头>奉化芋艿子;芋艿淀粉中绝大部分为快消化淀粉(60%),并含有一定量的慢消化淀粉和抗性淀粉。

气相色谱法测定黄精中甲胺磷残留量的不确定度评定

为评定使用气相色谱(GC)测定黄精中甲胺磷残留量的测量不确定度,本文依据《中华人民共和国药典》通则2341《农药残留测定法》、JJF 1135—2005《化学分析测量不确定度评定》、JJF 1059.1—2012《测量不确定度评定与表示》中的规定及要求,构建了数学模型,并对检测过程中各种不确定度的来源进行分析。结果显示,黄精中甲胺磷含量为0.213 mg/kg,其测量扩展不确定度为0.017 mg/kg(k=2,P=95%)。该方法的测量不确定度主要来自标准曲线拟合和标准溶液配制,贡献率分别为27.7%和37.2%,而由前处理过程中的样品提取液引入的不确定度分量最小,仅占1.1%。本模型可为使用气相色谱法测定农药残留量的不确定度评定提供可靠、准确的参考依据。

Fatigue-resistant Hydrogels

Hydrogels have been extensively studied for applications in various fields, such as tissue engineering and soft robotics, as determined by their mechanical properties. The mechanical design of hydrogels typically focuses on the modulus, toughness, and deformability. These characteristics play important roles and make great achievements for hydrogel use. In recent years, a growing body of research has concentrated on the fatigue property of hydrogels, which determines their resistance to crack propagation in the networks during cyclic mechanical loads for applications. However, knowledge of hydrogel fatigue behavior remains notably deficient. Here, we present a brief overview of the fatigue behavior of hydrogels, encompassing the general experimental methods to measure the fatigue property and fundamental theoretical calculation models. Then, we highlight multiple strategies to enhance the fatigue resistance of hydrogels. Finally, we present our perspectives on fatigue-resistant hydrogels, outstanding challenges and potential directions for future research.