Building Valveless Impedance Pumps From Biological Components: Progress and Challenges

Sarvazyan, Narine

doi:10.3389/fphys.2021.770906

Cited by 9 publications

(3 citation statements)

References 84 publications

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“…Another promising system within the realm of biomedical applications, boasting unique capabilities, is the impedance pump [ 18 ]. It offers a simple method of generating or amplifying flow without the need for valves or impellers [ 19 , 20 ].…”

Section: Introductionmentioning

confidence: 99%

Dielectric elastomer actuator-based valveless pump as Fontan failure assist device: introduction and preliminary study

Benouhiba,

Walter,

Jahren

et al. 2024

Interdisciplinary CardioVascular and Thoracic Surgery

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OBJECTIVES Fontan failure refers to a condition in which the Fontan circulation, a surgical procedure used to treat certain congenital heart defects, becomes insufficient, leading to compromised cardiac function and potential complications. This in vitro study therefore investigates the feasibility of bladeless impedance-driven cavopulmonary assist device via dielectric elastomer actuator (DEA) as a means to address Fontan failure. METHODS A cavopulmonary assist device, constructed using DEA technologies and employing the impedance pump concept, is subjected to in vitro testing within a closed-loop setup. This study aims to assess the device's functionality and performance under controlled conditions, providing valuable insights into its potential application as a cavopulmonary assistive technology. RESULTS The DEA-based pump, measuring 50 mm in length and 30 mm in diameter, is capable of achieving substantial flow rates within a closed-loop setup, reaching up to 1.20 l/min at an activation frequency of 4 Hz. It also provides a broad range of working internal pressures (<10 to >20 mmHg). Lastly, the properties of the flow (direction, magnitude, etc.) can be controlled by adjusting the input signal parameters (frequency, amplitude, etc.). CONCLUSIONS In summary, the results suggest that the valveless impedance-driven pump utilizing DEA technology is promising in the context of cavopulmonary assist devices. Further research and development in this area may lead to innovative and potentially more effective solutions for assisting the right heart, ultimately benefiting patients with heart-related health issues overall, with a particular focus on those experiencing Fontan failure.

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Section: Introductionmentioning

confidence: 99%

Dielectric elastomer actuator-based valveless pump as Fontan failure assist device: introduction and preliminary study

Benouhiba,

Walter,

Jahren

et al. 2024

Interdisciplinary CardioVascular and Thoracic Surgery

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“…Conversely, soft pumps reproduce the peristaltic motion observed in biological systems [4] by understanding and replicating motion primitives observed in nature [5], achieving high compliance and good flexibility. Soft peristaltic pumps generate pulsatile flow thanks to a travelling peristaltic contraction wave, unlikely Liebau pumps that exploit a periodic but spatially static contraction [6]. The bending capability of such devices makes them suitable for performing actuation in narrow and tight spaces with obstacles, such as medical applications [7].…”

Section: Introductionmentioning

confidence: 99%

Bioinspired Soft Bendable Peristaltic Pump Exploiting Ballooning for High Volume Throughput

Costi

Hughes

Biggins

et al. 2022

IEEE Trans. Med. Robot. Bionics

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Interest in bioinspired peristaltic pumps has grown in popularity among the scientific community in the last decade thanks to their extreme flexibility and their intrinsic compliance. In this paper, we propose a soft peristaltic pump exploiting ballooning. Our aim is to promote and propel forward the ballooned region by controlling the air pressure between the balloon and an external flexible containment tube, to achieve a peristaltic pumping motion with a simple design and using only one control signal. This paper describes the implementation of the pump and the inlet-pump-outlet system, provides an analytical model to predict the pump performance, and showcases experimental results. We also implement a computer simulation to further characterize the device. We show that it is possible to achieve high volumetric flow rates, up to 4.4 mL/s, with only a single control signal, paving the way for more flexible and easy to manufacture peristaltic pumps.

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“…Many researchers have carried out analytical [4] or computational studies [5] in a bid to better comprehend the mechanisms at work in the Liebau problem of valveless pumping in open [6] or closed-loop [7] systems. It is believed that Liebau pumping plays a crucial role in heart development and several other physiological processes [8]. Numerous distinctive features of the net flow produce by a Liebau effect pump are easily describe by wave dynamics [9,10].…”

Section: Introductionmentioning

confidence: 99%

Numerical Modelling of a Valveless Impedance Pump with Various Pinch Locations

Mahat

Jamali

Kasolang

2022

ARASET

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Microfluidics devices offers reliable transport mechanism to drive fluid within a microscale flow. This research work aims to identify the characteristic of flow in valveless impedance pump which uses acoustic impedance mismatch to drive flow using numerical simulations. The focus of the studies is designing a well performed pump where the required displacement of elastic wall can still be achieved even when the force applied in different locations and also a mechanism that requires low input current. Shear rate resulting from the pumping mechanism were measured at different input boundary conditions. Important parameters such as pinch location can affect the direction of the velocity magnitude and shear rate. It is found that the maximum shear rate occurred at 2 mm pinch location at 400 s-1. Hence, the pump design from this study can be used as the best application for microfluidic systems where a high pumping amount is desired.

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Building Valveless Impedance Pumps From Biological Components: Progress and Challenges

Cited by 9 publications

References 84 publications

Dielectric elastomer actuator-based valveless pump as Fontan failure assist device: introduction and preliminary study

Dielectric elastomer actuator-based valveless pump as Fontan failure assist device: introduction and preliminary study

Bioinspired Soft Bendable Peristaltic Pump Exploiting Ballooning for High Volume Throughput

Numerical Modelling of a Valveless Impedance Pump with Various Pinch Locations

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