基于脂蛋白代谢计算模型的诊断标记。

Daniël B van Schalkwijk, Ben van Ommen, Andreas P Freidig, Jan van der Greef, Albert A de Graaf
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引用次数: 12

摘要

背景:血脂异常是心血管疾病和II型糖尿病的重要危险因素。脂蛋白诊断,如低密度脂蛋白胆固醇和高密度脂蛋白胆固醇,有助于诊断这些疾病。脂蛋白谱测量可以改善脂蛋白诊断,但迄今为止,解释的复杂性限制了其临床应用。我们之前开发了一种称为粒子分析器的计算模型来解释脂蛋白谱。在目前的研究中,我们进一步开发和校准粒子分析器使用特定的遗传条件的受试者。随后,我们进行了技术验证,并从现有的脂蛋白浓度和代谢通量数据出发,初步研究了临床应用的适应症。由于模型结果不能直接测量,唯一可用的技术验证是确证。对于临床用途的初步指示,汇集了各种类型血脂异常的受试者的脂蛋白代谢通量数据。因此,我们研究了由粒子分析器得出的脂蛋白代谢比率如何区分报告的血脂异常和正常血脂受试者。结果:我们发现该模型可以很好地拟合16项研究中的15项中的正常血脂和异常血脂受试者,平均拟合误差为8.8%±5.0%;只有一项研究显示了更大的拟合误差。作为临床有用性的初步指标,我们发现一种基于VLDL代谢比率的诊断标志物比甘油三酯、HDL胆固醇或LDL胆固醇更能区分血脂异常和正常血脂受试者。VLDL代谢率分别优于每种经典诊断;在经典诊断的基础上,他们还在多元逻辑回归模型中增加了区分能力。结论:在这项研究中,我们进一步开发、校准和证实了粒子分析器计算模型,使用汇集的脂蛋白代谢通量数据。从血脂异常患者的脂蛋白代谢通量汇总数据中,我们得出了VLDL代谢比率,该比率比标准诊断(包括HDL胆固醇、甘油三酯和LDL胆固醇)更好地区分了正常血脂和血脂异常受试者。由于血脂异常与心血管疾病和II型糖尿病的发展密切相关,脂蛋白代谢比率是这些疾病的候选风险标志物。这些比率原则上可以通过将粒子分析器应用于单个脂蛋白剖面测量来获得,这使得临床应用可行。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Diagnostic markers based on a computational model of lipoprotein metabolism.

Diagnostic markers based on a computational model of lipoprotein metabolism.

Diagnostic markers based on a computational model of lipoprotein metabolism.

Diagnostic markers based on a computational model of lipoprotein metabolism.

Background: Dyslipidemia is an important risk factor for cardiovascular disease and type II diabetes. Lipoprotein diagnostics, such as LDL cholesterol and HDL cholesterol, help to diagnose these diseases. Lipoprotein profile measurements could improve lipoprotein diagnostics, but interpretational complexity has limited their clinical application to date. We have previously developed a computational model called Particle Profiler to interpret lipoprotein profiles. In the current study we further developed and calibrated Particle Profiler using subjects with specific genetic conditions. We subsequently performed technical validation and worked at an initial indication of clinical usefulness starting from available data on lipoprotein concentrations and metabolic fluxes. Since the model outcomes cannot be measured directly, the only available technical validation was corroboration. For an initial indication of clinical usefulness, pooled lipoprotein metabolic flux data was available from subjects with various types of dyslipidemia. Therefore we investigated how well lipoprotein metabolic ratios derived from Particle Profiler distinguished reported dyslipidemic from normolipidemic subjects.

Results: We found that the model could fit a range of normolipidemic and dyslipidemic subjects from fifteen out of sixteen studies equally well, with an average 8.8% ± 5.0% fit error; only one study showed a larger fit error. As initial indication of clinical usefulness, we showed that one diagnostic marker based on VLDL metabolic ratios better distinguished dyslipidemic from normolipidemic subjects than triglycerides, HDL cholesterol, or LDL cholesterol. The VLDL metabolic ratios outperformed each of the classical diagnostics separately; they also added power of distinction when included in a multivariate logistic regression model on top of the classical diagnostics.

Conclusions: In this study we further developed, calibrated, and corroborated the Particle Profiler computational model using pooled lipoprotein metabolic flux data. From pooled lipoprotein metabolic flux data on dyslipidemic patients, we derived VLDL metabolic ratios that better distinguished normolipidemic from dyslipidemic subjects than standard diagnostics, including HDL cholesterol, triglycerides and LDL cholesterol. Since dyslipidemias are closely linked to cardiovascular disease and diabetes type II development, lipoprotein metabolic ratios are candidate risk markers for these diseases. These ratios can in principle be obtained by applying Particle Profiler to a single lipoprotein profile measurement, which makes clinical application feasible.

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