Mark D. Rodefeld MD , Timothy Conover PhD , Richard Figliola PhD , Mike Neary MS , Guruprasad Giridharan PhD , Artem Ivashchenko MEng , Edward M. Bennett PhD
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Pump power is supplied by a systemic arterial shunt and radial turbine, with a closed-loop shunt return to the common atrium (Q<sub>P</sub>:Q<sub>S</sub> 1:1). Computational fluid dynamic analysis and lumped parameter modeling of pump impact on the Fontan circulation was performed.</div></div><div><h3>Results</h3><div>Findings indicate that a pump that can augment all 4 limbs of total cavopulmonary connection flow (superior vena cava/inferior vena cava inflow; left pulmonary artery/right pulmonary artery outflow) using a systemic arterial shunt powered turbine at a predicted cavopulmonary pressure rise of +2.5 mm Hg. Systemic shunt flow is 1.43 lumped parameter model, 22% cardiac output. Systemic venous pressure is reduced by 1.4 mm Hg with improved ventricular preload and cardiac output.</div></div><div><h3>Conclusions</h3><div>It may be possible to tap reserve pressure energy in the systemic circulation to improve Fontan circulatory efficiency. Further studies are warranted to optimize, fabricate, and test pump designs for hydraulic performance and hemocompatibility. Potential benefits of an autonomous Fontan pump include durable physiologic shift toward biventricular health, freedom from external power, autoregulating function and exercise responsiveness, and improved quality and duration of life.</div></div>","PeriodicalId":74032,"journal":{"name":"JTCVS open","volume":"21 ","pages":"Pages 257-266"},"PeriodicalIF":0.0000,"publicationDate":"2024-10-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Autonomous Fontan pump: Computational feasibility study\",\"authors\":\"Mark D. Rodefeld MD , Timothy Conover PhD , Richard Figliola PhD , Mike Neary MS , Guruprasad Giridharan PhD , Artem Ivashchenko MEng , Edward M. 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引用次数: 0
摘要
目的单心室生理学患者在接受丰坦(Fontan)姑息治疗后,终生处于慢性循环功能低下状态。这在很大程度上是由于缺乏肺下心室。低压上升腔肺辅助装置可以解决肺下腔不足的问题,并抵消丰坦悖论。我们研究了通过利用全身动脉循环中的储备压力能量自供电的丰坦泵的可行性。方法设计了一个双入口、双出口旋转泵,通过全腔肺连接增强丰坦血流。泵的动力由全身动脉分流器和径向涡轮提供,并通过闭环分流器返回普通心房(QP:QS 1:1)。结果研究结果表明,使用全身动脉分流驱动涡轮的泵可以增加腔肺总连接的所有四肢血流(上腔静脉/下腔静脉流入;左肺动脉/右肺动脉流出),而预测的腔肺压力升高为 +2.5 mm Hg。全身分流量为 1.43 个集合参数模型,心输出量为 22%。全身静脉压降低了 1.4 毫米汞柱,心室前负荷和心输出量得到改善。有必要开展进一步研究,以优化、制造和测试泵的水力性能和血液相容性。自主丰坦泵的潜在益处包括:向双心室健康的持久生理转变、摆脱外部动力、自动调节功能和运动反应能力,以及提高生活质量和延长寿命。
Autonomous Fontan pump: Computational feasibility study
Objective
After Fontan palliation, patients with single-ventricle physiology are committed to chronic circulatory inefficiency for the duration of their lives. This is due in large part to the lack of a subpulmonary ventricle. A low-pressure rise cavopulmonary assist device can address the subpulmonary deficit and offset the Fontan paradox. We investigated the feasibility of a Fontan pump that is self-powered by tapping reserve pressure energy in the systemic arterial circulation.
Methods
A double-inlet, double-outlet rotary pump was designed to augment Fontan flow through the total cavopulmonary connection. Pump power is supplied by a systemic arterial shunt and radial turbine, with a closed-loop shunt return to the common atrium (QP:QS 1:1). Computational fluid dynamic analysis and lumped parameter modeling of pump impact on the Fontan circulation was performed.
Results
Findings indicate that a pump that can augment all 4 limbs of total cavopulmonary connection flow (superior vena cava/inferior vena cava inflow; left pulmonary artery/right pulmonary artery outflow) using a systemic arterial shunt powered turbine at a predicted cavopulmonary pressure rise of +2.5 mm Hg. Systemic shunt flow is 1.43 lumped parameter model, 22% cardiac output. Systemic venous pressure is reduced by 1.4 mm Hg with improved ventricular preload and cardiac output.
Conclusions
It may be possible to tap reserve pressure energy in the systemic circulation to improve Fontan circulatory efficiency. Further studies are warranted to optimize, fabricate, and test pump designs for hydraulic performance and hemocompatibility. Potential benefits of an autonomous Fontan pump include durable physiologic shift toward biventricular health, freedom from external power, autoregulating function and exercise responsiveness, and improved quality and duration of life.