Composite Biomaterials System Lab, System Design Engineering Department, University of Waterloo, Ontario, Canada.
Department of Orthopaedic Surgery, Vanderbilt University Medical Center, Nashville, TN, United States of America; United States Department of Veterans Affairs, Tennessee Valley Healthcare System, Nashville, TN 37212, United States of America.
Bone. 2024 Sep;186:117139. doi: 10.1016/j.bone.2024.117139. Epub 2024 May 31.
This study sought to further develop and validate a previously proposed physics-based model that maps denaturation kinetics from differential scanning calorimetry (DSC) to the isometric tension generated during hydrothermal isometric tension (HIT) testing of collagenous tissues. The primary objectives of this study were to verify and validate two physics-based model parameters: α, which indicates the amount of instantaneous isometric tension developed per unit of collagen denaturation, and β, which captures the proportionality between temperature and the generated isometric tension post denaturation initiation. These parameters were used as measures of bone collagen quality, employing data from HIT and DSC testing of human bone collagen from two previous studies. Additionally, given the physical basis of the model, the study aimed to further validate Max.Slope, the rate of change in isometric tensile stress with change in temperature, as an independent measure of collagen network connectivity. Max.Slope has previously been positively correlated with measures of cortical bone fracture resistance. Towards this verification and validation, the hypotheses were a) that α would correlate strongly with HIT denaturation temperature, T, and the enthalpy of melting (ΔH) from DSC, and b) that β would correlate positively and strongly with Max.Slope. The model was employed in the analysis of HIT-DSC data from the testing of demineralized bone collagen isolated from cadaveric human femurs in two prior studies. In one study, data were collected from HIT-DSC testing of cortical bone collagen from 74 donors. Among them, 38 had a history of type 2 diabetes +/- chronic kidney disease, while the remaining 36 had no history of T2D again with or without CKD. Cortical bone specimens were extracted from the lateral mid-shaft. The second study involved 15 donor femora, with four cortical bone specimens extracted from each. Of these four, two specimens underwent a 4-week incubation in 0.1 M ribose at 37 °C to induce non-enzymatic ribation and advanced glycation endproducts, while the other two served as non-ribated controls. The examination involved investigating correlations between the model parameters α and β and various measures, such as Max.Slope, Td, ΔH, age, and duration of type 2 diabetes. The results revealed positive correlations between the model parameter β and Max.Slope (r = 0.55-0.58). The parameter α was found to be associated with T, but also sensitive to the shape of the HIT curve around T resulting in difficulties with variability and interpretation. As a result, while both hypotheses are confirmed, Max.Slope and β are better indicators of bone collagen quality because they are measures of the connectivity or, more generally, the integrity of the bone collagen network.
本研究旨在进一步开发和验证先前提出的物理模型,该模型将差示扫描量热法(DSC)中的变性动力学映射到胶原组织水热等长张力(HIT)测试中的等长张力。本研究的主要目的是验证和验证两个物理模型参数:α,它表示单位胶原变性产生的瞬时等长张力的量,以及β,它捕捉了变性起始后温度与产生的等长张力之间的比例关系。这些参数被用作骨胶原质量的衡量标准,使用了来自之前两项研究中人体骨胶原的 HIT 和 DSC 测试数据。此外,由于该模型的物理基础,研究旨在进一步验证 Max.Slope,即等长拉伸应力随温度变化的变化率,作为胶原网络连通性的独立衡量标准。Max.Slope 先前与皮质骨断裂阻力的衡量标准呈正相关。为了验证和验证,假设 a)α与 HIT 变性温度 T 和 DSC 中的熔融焓(ΔH)高度相关,b)β与 Max.Slope 呈正相关且高度相关。该模型用于分析来自之前两项研究中从尸体人股骨中分离的脱矿骨胶原的 HIT-DSC 数据。在一项研究中,从 74 名供体的皮质骨胶原的 HIT-DSC 测试中收集数据。其中,38 人患有 2 型糖尿病 +/- 慢性肾脏病,而其余 36 人没有 2 型糖尿病病史,也没有再次出现 CKD。皮质骨标本取自外侧中轴。第二项研究涉及 15 个供体股骨,每个股骨提取四个皮质骨标本。其中,两个标本在 37°C 的 0.1M 核糖中孵育 4 周,以诱导非酶核糖化和晚期糖基化终产物,而另外两个则作为未核糖化对照。检查包括研究模型参数α和β与各种测量值(如 Max.Slope、Td、ΔH、年龄和 2 型糖尿病持续时间)之间的相关性。结果表明,模型参数β与 Max.Slope 呈正相关(r=0.55-0.58)。参数α与 T 相关,但也对 HIT 曲线在 T 周围的形状敏感,导致变异性和解释困难。因此,虽然两个假设都得到了证实,但 Max.Slope 和β是骨胶原质量的更好指标,因为它们是胶原网络连通性或更一般的完整性的衡量标准。
