Compliant Buckled Foam Actuators and Application in Patient-Specific Direct Cardiac Compression

Affiliations

¹ 1 Department of Materials Science and Engineering, Cornell University , Ithaca, New York.
² 2 Department of Mechanical and Aerospace Engineering, Cornell University , Ithaca, New York.
³ 3 Department of Radiology, Weill Cornell Medicine , New York, New York.
⁴ 4 Dalio Institute of Cardiovascular Imaging , New York, New York.

PMID: 29412085
PMCID: PMC5804100
DOI: 10.1089/soro.2017.0018

Compliant Buckled Foam Actuators and Application in Patient-Specific Direct Cardiac Compression

Benjamin C Mac Murray et al. Soft Robot. 2018 Feb.

. 2018 Feb;5(1):99-108.

doi: 10.1089/soro.2017.0018. Epub 2017 Oct 26.

Authors

Affiliations

¹ 1 Department of Materials Science and Engineering, Cornell University , Ithaca, New York.
² 2 Department of Mechanical and Aerospace Engineering, Cornell University , Ithaca, New York.
³ 3 Department of Radiology, Weill Cornell Medicine , New York, New York.
⁴ 4 Dalio Institute of Cardiovascular Imaging , New York, New York.

PMID: 29412085
PMCID: PMC5804100
DOI: 10.1089/soro.2017.0018

Abstract

We introduce the use of buckled foam for soft pneumatic actuators. A moderate amount of residual compressive strain within elastomer foam increases the applied force ∼1.4 × or stroke ∼2 × compared with actuators without residual strain. The origin of these improved characteristics is explained analytically. These actuators are applied in a direct cardiac compression (DCC) device design, a type of implanted mechanical circulatory support that avoids direct blood contact, mitigating risks of clot formation and stroke. This article describes a first step toward a pneumatically powered, patient-specific DCC design by employing elastomer foam as the mechanism for cardiac compression. To form the device, a mold of a patient's heart was obtained by 3D printing a digitized X-ray computed tomography or magnetic resonance imaging scan into a solid model. From this model, a soft, robotic foam DCC device was molded. The DCC device is compliant and uses compressed air to inflate foam chambers that in turn apply compression to the exterior of a heart. The device is demonstrated on a porcine heart and is capable of assisting heart pumping at physiologically relevant durations (∼200 ms for systole and ∼400 ms for diastole) and stroke volumes (∼70 mL). Although further development is necessary to produce a fully implantable device, the material and processing insights presented here are essential to the implementation of a foam-based, patient-specific DCC design.

Keywords: direct cardiac compression; elastomer foam; patient-specific device; pneumatic actuation.

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Conflict of interest statement

No competing financial interests exist.

Figures

<b>FIG. 1.</b> — **FIG. 1.**
The direct cardiac compression device concept. **(A)** The device fabrication process involves the following steps: collection of a chest MRI or CT of the patient's heart, reconstructing a digital 3D model of the heart, digitally isolating the heart, 3D printing a mold from the digital heart model, casting elastomer foam within the mold, and cropping and assembling two foam chambers to form the final DCC device. Scale bar, 3 cm. **(B)** A device schematic showing elastomer and strain limiting layers surrounding the foam actuation chambers. Scale bar, 250 μm. **(C)** The device before inflation (*left*) and during inflation (*right*) with *arrows* showing volume displacement upon pressurization. Scale bar, 3 cm. CT, computed tomography; DCC, direct cardiac compression; MRI, magnetic resonance imaging. Color images available online at www.liebertpub.com/soro

<b>FIG. 2.</b> — **FIG. 2.**
The compressive behavior of polyurethane foams. **(A)** Mechanical compression of the foams used in this study, **(B)** a schematic of constrained compression method, and **(C)** a foam cube before (*left*) and after constrained triaxial compression to ∼40% original volume (*right*). Scale bar, 5 mm. **(D, E)** μCT 3D reconstruction (*left*), a representative 2D slice (*right*), and pore size distribution (lower) of uncompressed and triaxially compressed foam. Scale bars, 500 μm. μCT, microcomputed tomography. Color images available online at www.liebertpub.com/soro

<b>FIG. 3.</b> — **FIG. 3.**
The effect of foam compression on actuation. Extending actuation of an uncompressed (*left*) and compressed foam actuator (*right*). Scale bar, 5 mm. Color images available online at www.liebertpub.com/soro

<b>FIG. 4.</b> — **FIG. 4.**
Fabrication of the DCC device. **(A)** The porcine heart that served as the basis for the digitally designed mold **(B)** that was used to form an organ-specific foam shell. Scale bar, 2 cm. **(C)** The compressed foam inflation chambers that were coated in carbon fiber and sealed with elastomer to form the final DCC device **(D)** that fit well around the original heart **(E)**. Color images available online at www.liebertpub.com/soro

<b>FIG. 5.</b> — **FIG. 5.**
DCC device benchtop and *ex vivo* performance. **(A)** Photo sequence of chamber inflation and deflation corresponding to maximum and minimum actuation pressures **(B)** recorded by an in-line analog sensor. The *shaded areas* indicate the duration of inflation triggered by a simulated ECG reading **(C)**. Scale bar, 2 cm. Video available in Supplementary Data. Color images available online at www.liebertpub.com/soro

<b>FIG. 6.</b> — **FIG. 6.**
*Ex vivo* demonstration on porcine heart. **(A)** The device setup for the *ex vivo* demonstration on the porcine heart with **(B)** the collected air line pressure measurements and corresponding water flow rate during *ex vivo* demonstration on the porcine heart. Video available in Supplementary Data. Color images available online at www.liebertpub.com/soro

See this image and copyright information in PMC

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Compliant Buckled Foam Actuators and Application in Patient-Specific Direct Cardiac Compression

Affiliations

Compliant Buckled Foam Actuators and Application in Patient-Specific Direct Cardiac Compression

Authors

Affiliations

Abstract

Conflict of interest statement

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