Dynamic loading of human engineered heart tissue enhances contractile function and drives a desmosome-linked disease phenotype

Jacqueline M. Bliley; Mathilde C.S.C. Vermeer; Rebecca M. Duffy; Ivan Batalov; Duco Kramer; Joshua W. Tashman; Daniel J. Shiwarski; Andrew Lee; Alexander S. Teplenin; Linda Volkers; Brian Coffin; Martijn F. Hoes; Anna Kalmykov; Rachelle N. Palchesko; Yan Sun; Jan D.H. Jongbloed; Nils Bomer; Rudolf A. De Boer; Albert J.H. Suurmeijer; Daniel P. Daniel; Maria C. Bolling; Peter Van der Meer; Adam W. Feinberg

doi:10.1126/scitranslmed.abd1817

Dynamic loading of human engineered heart tissue enhances contractile function and drives a desmosome-linked disease phenotype

Jacqueline M. Bliley, Mathilde C.S.C. Vermeer, Rebecca M. Duffy, Ivan Batalov, Duco Kramer, Joshua W. Tashman, Daniel J. Shiwarski, Andrew Lee, Alexander S. Teplenin, Linda Volkers, Brian Coffin, Martijn F. Hoes, Anna Kalmykov, Rachelle N. Palchesko, Yan Sun, Jan D.H. Jongbloed, Nils Bomer, Rudolf A. De Boer, Albert J.H. Suurmeijer, Daniel P. DanielMaria C. Bolling, Peter Van der Meer^*, Adam W. Feinberg^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

74 Citations (Scopus)

Abstract

The role that mechanical forces play in shaping the structure and function of the heart is critical to understanding heart formation and the etiology of disease but is challenging to study in patients. Engineered heart tissues (EHTs) incorporating human induced pluripotent stem cell (hiPSC)-derived cardiomyocytes have the potential to provide insight into these adaptive and maladaptive changes. However, most EHT systems cannot model both preload (stretch during chamber filling) and afterload (pressure the heart must work against to eject blood). Here, we have developed a new dynamic EHT (dyn-EHT) model that enables us to tune preload and have unconstrained contractile shortening of >10%. To do this, three-dimensional (3D) EHTs were integrated with an elastic polydimethylsiloxane strip providing mechanical preload and afterload in addition to enabling contractile force measurements based on strip bending. Our results demonstrated that dynamic loading improves the function of wild-type EHTs on the basis of the magnitude of the applied force, leading to improved alignment, conduction velocity, and contractility. For disease modeling, we used hiPSC-derived cardiomyocytes from a patient with arrhythmogenic cardiomyopathy due to mutations in the desmoplakin gene. We demonstrated that manifestation of this desmosome-linked disease state required dyn-EHT conditioning and that it could not be induced using 2D or standard 3D EHT approaches. Thus, a dynamic loading strategy is necessary to provoke the disease phenotype of diastolic lengthening, reduction of desmosome counts, and reduced contractility, which are related to primary end points of clinical disease, such as chamber thinning and reduced cardiac output.

Original language	English
Article number	eabd1817
Journal	Science Translational Medicine
Volume	13
Issue number	603
DOIs	https://doi.org/10.1126/scitranslmed.abd1817
Publication status	Published - 21 Jul 2021
Externally published	Yes

Bibliographical note

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© 2021 American Association for the Advancement of Science. All rights reserved.

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Bliley, J. M., Vermeer, M. C. S. C., Duffy, R. M., Batalov, I., Kramer, D., Tashman, J. W., Shiwarski, D. J., Lee, A., Teplenin, A. S., Volkers, L., Coffin, B., Hoes, M. F., Kalmykov, A., Palchesko, R. N., Sun, Y., Jongbloed, J. D. H., Bomer, N., De Boer, R. A., Suurmeijer, A. J. H., ... Feinberg, A. W. (2021). Dynamic loading of human engineered heart tissue enhances contractile function and drives a desmosome-linked disease phenotype. Science Translational Medicine, 13(603), Article eabd1817. https://doi.org/10.1126/scitranslmed.abd1817

@article{57ad13e1bf2a4a8fb30277c813223daa,

title = "Dynamic loading of human engineered heart tissue enhances contractile function and drives a desmosome-linked disease phenotype",

abstract = "The role that mechanical forces play in shaping the structure and function of the heart is critical to understanding heart formation and the etiology of disease but is challenging to study in patients. Engineered heart tissues (EHTs) incorporating human induced pluripotent stem cell (hiPSC)-derived cardiomyocytes have the potential to provide insight into these adaptive and maladaptive changes. However, most EHT systems cannot model both preload (stretch during chamber filling) and afterload (pressure the heart must work against to eject blood). Here, we have developed a new dynamic EHT (dyn-EHT) model that enables us to tune preload and have unconstrained contractile shortening of >10\%. To do this, three-dimensional (3D) EHTs were integrated with an elastic polydimethylsiloxane strip providing mechanical preload and afterload in addition to enabling contractile force measurements based on strip bending. Our results demonstrated that dynamic loading improves the function of wild-type EHTs on the basis of the magnitude of the applied force, leading to improved alignment, conduction velocity, and contractility. For disease modeling, we used hiPSC-derived cardiomyocytes from a patient with arrhythmogenic cardiomyopathy due to mutations in the desmoplakin gene. We demonstrated that manifestation of this desmosome-linked disease state required dyn-EHT conditioning and that it could not be induced using 2D or standard 3D EHT approaches. Thus, a dynamic loading strategy is necessary to provoke the disease phenotype of diastolic lengthening, reduction of desmosome counts, and reduced contractility, which are related to primary end points of clinical disease, such as chamber thinning and reduced cardiac output.",

author = "Bliley, \{Jacqueline M.\} and Vermeer, \{Mathilde C.S.C.\} and Duffy, \{Rebecca M.\} and Ivan Batalov and Duco Kramer and Tashman, \{Joshua W.\} and Shiwarski, \{Daniel J.\} and Andrew Lee and Teplenin, \{Alexander S.\} and Linda Volkers and Brian Coffin and Hoes, \{Martijn F.\} and Anna Kalmykov and Palchesko, \{Rachelle N.\} and Yan Sun and Jongbloed, \{Jan D.H.\} and Nils Bomer and \{De Boer\}, \{Rudolf A.\} and Suurmeijer, \{Albert J.H.\} and Daniel, \{Daniel P.\} and Bolling, \{Maria C.\} and \{Van der Meer\}, Peter and Feinberg, \{Adam W.\}",

year = "2021",

month = jul,

day = "21",

doi = "10.1126/scitranslmed.abd1817",

language = "English",

volume = "13",

journal = "Science Translational Medicine",

issn = "1946-6234",

publisher = "American Association for the Advancement of Science",

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Bliley, JM, Vermeer, MCSC, Duffy, RM, Batalov, I, Kramer, D, Tashman, JW, Shiwarski, DJ, Lee, A, Teplenin, AS, Volkers, L, Coffin, B, Hoes, MF, Kalmykov, A, Palchesko, RN, Sun, Y, Jongbloed, JDH, Bomer, N, De Boer, RA, Suurmeijer, AJH, Daniel, DP, Bolling, MC, Van der Meer, P & Feinberg, AW 2021, 'Dynamic loading of human engineered heart tissue enhances contractile function and drives a desmosome-linked disease phenotype', Science Translational Medicine, vol. 13, no. 603, eabd1817. https://doi.org/10.1126/scitranslmed.abd1817

TY - JOUR

T1 - Dynamic loading of human engineered heart tissue enhances contractile function and drives a desmosome-linked disease phenotype

AU - Bliley, Jacqueline M.

AU - Vermeer, Mathilde C.S.C.

AU - Duffy, Rebecca M.

AU - Batalov, Ivan

AU - Kramer, Duco

AU - Tashman, Joshua W.

AU - Shiwarski, Daniel J.

AU - Lee, Andrew

AU - Teplenin, Alexander S.

AU - Volkers, Linda

AU - Coffin, Brian

AU - Hoes, Martijn F.

AU - Kalmykov, Anna

AU - Palchesko, Rachelle N.

AU - Sun, Yan

AU - Jongbloed, Jan D.H.

AU - Bomer, Nils

AU - De Boer, Rudolf A.

AU - Suurmeijer, Albert J.H.

AU - Daniel, Daniel P.

AU - Bolling, Maria C.

AU - Van der Meer, Peter

AU - Feinberg, Adam W.

PY - 2021/7/21

Y1 - 2021/7/21

N2 - The role that mechanical forces play in shaping the structure and function of the heart is critical to understanding heart formation and the etiology of disease but is challenging to study in patients. Engineered heart tissues (EHTs) incorporating human induced pluripotent stem cell (hiPSC)-derived cardiomyocytes have the potential to provide insight into these adaptive and maladaptive changes. However, most EHT systems cannot model both preload (stretch during chamber filling) and afterload (pressure the heart must work against to eject blood). Here, we have developed a new dynamic EHT (dyn-EHT) model that enables us to tune preload and have unconstrained contractile shortening of >10%. To do this, three-dimensional (3D) EHTs were integrated with an elastic polydimethylsiloxane strip providing mechanical preload and afterload in addition to enabling contractile force measurements based on strip bending. Our results demonstrated that dynamic loading improves the function of wild-type EHTs on the basis of the magnitude of the applied force, leading to improved alignment, conduction velocity, and contractility. For disease modeling, we used hiPSC-derived cardiomyocytes from a patient with arrhythmogenic cardiomyopathy due to mutations in the desmoplakin gene. We demonstrated that manifestation of this desmosome-linked disease state required dyn-EHT conditioning and that it could not be induced using 2D or standard 3D EHT approaches. Thus, a dynamic loading strategy is necessary to provoke the disease phenotype of diastolic lengthening, reduction of desmosome counts, and reduced contractility, which are related to primary end points of clinical disease, such as chamber thinning and reduced cardiac output.

AB - The role that mechanical forces play in shaping the structure and function of the heart is critical to understanding heart formation and the etiology of disease but is challenging to study in patients. Engineered heart tissues (EHTs) incorporating human induced pluripotent stem cell (hiPSC)-derived cardiomyocytes have the potential to provide insight into these adaptive and maladaptive changes. However, most EHT systems cannot model both preload (stretch during chamber filling) and afterload (pressure the heart must work against to eject blood). Here, we have developed a new dynamic EHT (dyn-EHT) model that enables us to tune preload and have unconstrained contractile shortening of >10%. To do this, three-dimensional (3D) EHTs were integrated with an elastic polydimethylsiloxane strip providing mechanical preload and afterload in addition to enabling contractile force measurements based on strip bending. Our results demonstrated that dynamic loading improves the function of wild-type EHTs on the basis of the magnitude of the applied force, leading to improved alignment, conduction velocity, and contractility. For disease modeling, we used hiPSC-derived cardiomyocytes from a patient with arrhythmogenic cardiomyopathy due to mutations in the desmoplakin gene. We demonstrated that manifestation of this desmosome-linked disease state required dyn-EHT conditioning and that it could not be induced using 2D or standard 3D EHT approaches. Thus, a dynamic loading strategy is necessary to provoke the disease phenotype of diastolic lengthening, reduction of desmosome counts, and reduced contractility, which are related to primary end points of clinical disease, such as chamber thinning and reduced cardiac output.

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U2 - 10.1126/scitranslmed.abd1817

DO - 10.1126/scitranslmed.abd1817

M3 - Article

C2 - 34290054

AN - SCOPUS:85112517817

SN - 1946-6234

VL - 13

JO - Science Translational Medicine

JF - Science Translational Medicine

IS - 603

M1 - eabd1817

ER -

Dynamic loading of human engineered heart tissue enhances contractile function and drives a desmosome-linked disease phenotype

Abstract

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