肾切除术中失血量的数学模型

IF 1.8 Q3 MECHANICS
Fluids Pub Date : 2023-12-10 DOI:10.3390/fluids8120316
James Cowley, Xichun Luo, Grant D. Stewart, Wenmiao Shu, A. Kazakidi
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引用次数: 0

摘要

2021 年,约 51% 的肾肿瘤患者接受了手术切除。减少手术并发症的一个可行方法是最大限度地减少相关失血,在肾部分切除术中,失血是由于在切除肿瘤时对肾脏内的分支动脉修复不足造成的。肾脏血管的性质特别复杂,由各种相互连接的血管和许多分叉点、三叉点、四叉点和五叉点组成。在本研究中,我们假定整个肾脏为非牛顿卡氏流体,提出了一个整块参数数学模型,作为估算切断单根或多根血管引起的失血量的第一近似值。该模型显示,切断肾脏血管中的一条或多条血管会导致血液流速和压力重新分配到未改变的肾脏部分。该模型可以解释血管网络总阻抗的变化,并考虑各种多重切割。通过计算多种动脉切口组合的失血量,我们可以确定在肾部分切除术中最大限度减少失血量所需的适当手术方案,还能加深我们对灌注的理解,并考虑到细胞坏死的可能性。该模型可帮助肾脏外科医生在部分器官切除术中评估剩余血管是否足以支持器官存活。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Mathematical Model of Blood Loss during Renal Resection
In 2021, approximately 51% of patients diagnosed with kidney tumors underwent surgical resections. One possible way to reduce complications from surgery is to minimise the associated blood loss, which, in the case of partial nephrectomy, is caused by the inadequate repair of branching arteries within the kidney cut during the tumor resection. The kidney vasculature is particularly complicated in nature, consisting of various interconnecting blood vessels and numerous bifurcation, trifurcation, tetrafurcation, and pentafurcation points. In this study, we present a mathematical lumped-parameter model of a whole kidney, assuming a non-Newtonian Carreau fluid, as a first approximation of estimating the blood loss arising from the cutting of single or multiple vessels. It shows that severing one or more blood vessels from the kidney vasculature results in a redistribution of the blood flow rates and pressures to the unaltered section of the kidney. The model can account for the change in the total impedance of the vascular network and considers a variety of multiple cuts. Calculating the blood loss for numerous combinations of arterial cuts allows us to identify the appropriate surgical protocols required to minimise blood loss during partial nephrectomy as well as enhance our understanding of perfusion and account for the possibility of cellular necrosis. This model may help renal surgeons during partial organ resection in assessing whether the remaining vascularisation is sufficient to support organ viability.
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来源期刊
Fluids
Fluids Engineering-Mechanical Engineering
CiteScore
3.40
自引率
10.50%
发文量
326
审稿时长
12 weeks
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