Molecular Changes In Cardiac Tissue As A New Marker To Predict Cardiac Dysfunction Induced By Radiotherapy

Sónia Ribeiro; Ana Rita Simões; Filipe Rocha; Inês Sofia Vala; Ana Teresa Pinto; Augusto Ministro; Esmeralda Poli; Isabel Maria Diegues; Filomena Pina; Mohamed Amine Benadjaoud; Stephane Flamant; Radia Tamarat; Hugo Osório; Diogo Pais; Diogo Casal; Fausto José Pinto; Rune Matthiesen; Manuela Fiuza; Susana Constantino Rosa Santos

doi:10.3389/fonc.2022.945521

Molecular Changes In Cardiac Tissue As A New Marker To Predict Cardiac Dysfunction Induced By Radiotherapy

Sónia Ribeiro, Ana Rita Simões, Filipe Rocha, Inês Sofia Vala, Ana Teresa Pinto, Augusto Ministro, Esmeralda Poli, Isabel Maria Diegues, Filomena Pina, Mohamed Amine Benadjaoud, Stephane Flamant, Radia Tamarat, Hugo Osório, Diogo Pais, Diogo Casal, Fausto José Pinto, Rune Matthiesen, Manuela Fiuza, Susana Constantino Rosa Santos

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Abstract

The contribution of radiotherapy, per se, to late cardiotoxicity remains controversial. To clarify its impact on the development of early cardiac dysfunction, we developed an experimental model in which the hearts of rats were exposed, in a fractionated plan, to clinically relevant doses of ionizing radiation for oncological patients that undergo thoracic radiotherapy. Rat hearts were exposed to daily doses of 0.04, 0.3, and 1.2 Gy for 23 days, achieving cumulative doses of 0.92, 6.9, and 27.6 Gy, respectively. We demonstrate that myocardial deformation, assessed by global longitudinal strain, was impaired (a relative percentage reduction of >15% from baseline) in a dose-dependent manner at 18 months. Moreover, by scanning electron microscopy, the microvascular density in the cardiac apex was significantly decreased exclusively at 27.6 Gy dosage. Before GLS impairment detection, several tools (qRT-PCR, mass spectrometry, and western blot) were used to assess molecular changes in the cardiac tissue. The number/expression of several genes, proteins, and KEGG pathways, related to inflammation, fibrosis, and cardiac muscle contraction, were differently expressed in the cardiac tissue according to the cumulative dose. Subclinical cardiac dysfunction occurs in a dose-dependent manner as detected by molecular changes in cardiac tissue, a predictor of the severity of global longitudinal strain impairment. Moreover, there was no dose threshold below which no myocardial deformation impairment was detected. Our findings i) contribute to developing new markers and exploring non-invasive magnetic resonance imaging to assess cardiac tissue changes as an early predictor of cardiac dysfunction; ii) should raise red flags, since there is no dose threshold below which no myocardial deformation impairment was detected and should be considered in radiation-based imaging and -guided therapeutic cardiac procedures; and iii) highlights the need for personalized clinical approaches.

Original language	English
Article number	945521
Journal	Frontiers in Oncology
Volume	12
DOIs	https://doi.org/10.3389/fonc.2022.945521
Publication status	Published - 26 Jul 2022

Keywords

cardiac dysfunction
cardiac muscle
cardiotoxicity
global longitudinal strain (GLS)
microvasculature
radiotherapy

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.3389/fonc.2022.945521

fonc-12-945521Final published version, 4.09 MBLicence: CC BY

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Ribeiro, S., Simões, A. R., Rocha, F., Vala, I. S., Pinto, A. T., Ministro, A., Poli, E., Diegues, I. M., Pina, F., Benadjaoud, M. A., Flamant, S., Tamarat, R., Osório, H., Pais, D., Casal, D., Pinto, F. J., Matthiesen, R., Fiuza, M., & Constantino Rosa Santos, S. (2022). Molecular Changes In Cardiac Tissue As A New Marker To Predict Cardiac Dysfunction Induced By Radiotherapy. Frontiers in Oncology, 12, [945521]. https://doi.org/10.3389/fonc.2022.945521

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title = "Molecular Changes In Cardiac Tissue As A New Marker To Predict Cardiac Dysfunction Induced By Radiotherapy",

abstract = "The contribution of radiotherapy, per se, to late cardiotoxicity remains controversial. To clarify its impact on the development of early cardiac dysfunction, we developed an experimental model in which the hearts of rats were exposed, in a fractionated plan, to clinically relevant doses of ionizing radiation for oncological patients that undergo thoracic radiotherapy. Rat hearts were exposed to daily doses of 0.04, 0.3, and 1.2 Gy for 23 days, achieving cumulative doses of 0.92, 6.9, and 27.6 Gy, respectively. We demonstrate that myocardial deformation, assessed by global longitudinal strain, was impaired (a relative percentage reduction of >15% from baseline) in a dose-dependent manner at 18 months. Moreover, by scanning electron microscopy, the microvascular density in the cardiac apex was significantly decreased exclusively at 27.6 Gy dosage. Before GLS impairment detection, several tools (qRT-PCR, mass spectrometry, and western blot) were used to assess molecular changes in the cardiac tissue. The number/expression of several genes, proteins, and KEGG pathways, related to inflammation, fibrosis, and cardiac muscle contraction, were differently expressed in the cardiac tissue according to the cumulative dose. Subclinical cardiac dysfunction occurs in a dose-dependent manner as detected by molecular changes in cardiac tissue, a predictor of the severity of global longitudinal strain impairment. Moreover, there was no dose threshold below which no myocardial deformation impairment was detected. Our findings i) contribute to developing new markers and exploring non-invasive magnetic resonance imaging to assess cardiac tissue changes as an early predictor of cardiac dysfunction; ii) should raise red flags, since there is no dose threshold below which no myocardial deformation impairment was detected and should be considered in radiation-based imaging and -guided therapeutic cardiac procedures; and iii) highlights the need for personalized clinical approaches.",

keywords = "cardiac dysfunction, cardiac muscle, cardiotoxicity, global longitudinal strain (GLS), microvasculature, radiotherapy",

author = "S{\'o}nia Ribeiro and Sim{\~o}es, {Ana Rita} and Filipe Rocha and Vala, {In{\^e}s Sofia} and Pinto, {Ana Teresa} and Augusto Ministro and Esmeralda Poli and Diegues, {Isabel Maria} and Filomena Pina and Benadjaoud, {Mohamed Amine} and Stephane Flamant and Radia Tamarat and Hugo Os{\'o}rio and Diogo Pais and Diogo Casal and Pinto, {Fausto Jos{\'e}} and Rune Matthiesen and Manuela Fiuza and {Constantino Rosa Santos}, Susana",

note = "Funding Information: This work was supported by the European Community{\textquoteright}s Horizon 2020 Program supported the MEDIRAD—Implications of Medical Low Dose Radiation Exposure granted by the Euratom Research and Training Program 2014-2014 under agreement No. 755523. The MS work was financed by the Portuguese Mass Spectrometry Network, integrated in the National Roadmap of Research Infrastructures of Strategic Relevance (ROTEIRO/0028/2013; LISBOA-01-0145-FEDER-022125). ARP and ATP were supported by a fellowship (SFRH/BD/121684/2016 and SFRH/BPD/123181/2016, respectively) and IV received a fellowship for Programmatic Funding (UIDP/00306/2020), all from Funda{\c c}{\~a}o para a Ci{\^e}ncia e Tecnologia. ",

year = "2022",

month = jul,

day = "26",

doi = "10.3389/fonc.2022.945521",

language = "English",

volume = "12",

journal = "Frontiers in Oncology",

issn = "2234-943X",

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Ribeiro, S, Simões, AR, Rocha, F, Vala, IS, Pinto, AT, Ministro, A, Poli, E, Diegues, IM, Pina, F, Benadjaoud, MA, Flamant, S, Tamarat, R, Osório, H, Pais, D , Casal, D, Pinto, FJ, Matthiesen, R, Fiuza, M & Constantino Rosa Santos, S 2022, 'Molecular Changes In Cardiac Tissue As A New Marker To Predict Cardiac Dysfunction Induced By Radiotherapy', Frontiers in Oncology, vol. 12, 945521. https://doi.org/10.3389/fonc.2022.945521

TY - JOUR

T1 - Molecular Changes In Cardiac Tissue As A New Marker To Predict Cardiac Dysfunction Induced By Radiotherapy

AU - Ribeiro, Sónia

AU - Simões, Ana Rita

AU - Rocha, Filipe

AU - Vala, Inês Sofia

AU - Pinto, Ana Teresa

AU - Ministro, Augusto

AU - Poli, Esmeralda

AU - Diegues, Isabel Maria

AU - Pina, Filomena

AU - Benadjaoud, Mohamed Amine

AU - Flamant, Stephane

AU - Tamarat, Radia

AU - Osório, Hugo

AU - Pais, Diogo

AU - Casal, Diogo

AU - Pinto, Fausto José

AU - Matthiesen, Rune

AU - Fiuza, Manuela

AU - Constantino Rosa Santos, Susana

N1 - Funding Information: This work was supported by the European Community’s Horizon 2020 Program supported the MEDIRAD—Implications of Medical Low Dose Radiation Exposure granted by the Euratom Research and Training Program 2014-2014 under agreement No. 755523. The MS work was financed by the Portuguese Mass Spectrometry Network, integrated in the National Roadmap of Research Infrastructures of Strategic Relevance (ROTEIRO/0028/2013; LISBOA-01-0145-FEDER-022125). ARP and ATP were supported by a fellowship (SFRH/BD/121684/2016 and SFRH/BPD/123181/2016, respectively) and IV received a fellowship for Programmatic Funding (UIDP/00306/2020), all from Fundação para a Ciência e Tecnologia.

PY - 2022/7/26

Y1 - 2022/7/26

N2 - The contribution of radiotherapy, per se, to late cardiotoxicity remains controversial. To clarify its impact on the development of early cardiac dysfunction, we developed an experimental model in which the hearts of rats were exposed, in a fractionated plan, to clinically relevant doses of ionizing radiation for oncological patients that undergo thoracic radiotherapy. Rat hearts were exposed to daily doses of 0.04, 0.3, and 1.2 Gy for 23 days, achieving cumulative doses of 0.92, 6.9, and 27.6 Gy, respectively. We demonstrate that myocardial deformation, assessed by global longitudinal strain, was impaired (a relative percentage reduction of >15% from baseline) in a dose-dependent manner at 18 months. Moreover, by scanning electron microscopy, the microvascular density in the cardiac apex was significantly decreased exclusively at 27.6 Gy dosage. Before GLS impairment detection, several tools (qRT-PCR, mass spectrometry, and western blot) were used to assess molecular changes in the cardiac tissue. The number/expression of several genes, proteins, and KEGG pathways, related to inflammation, fibrosis, and cardiac muscle contraction, were differently expressed in the cardiac tissue according to the cumulative dose. Subclinical cardiac dysfunction occurs in a dose-dependent manner as detected by molecular changes in cardiac tissue, a predictor of the severity of global longitudinal strain impairment. Moreover, there was no dose threshold below which no myocardial deformation impairment was detected. Our findings i) contribute to developing new markers and exploring non-invasive magnetic resonance imaging to assess cardiac tissue changes as an early predictor of cardiac dysfunction; ii) should raise red flags, since there is no dose threshold below which no myocardial deformation impairment was detected and should be considered in radiation-based imaging and -guided therapeutic cardiac procedures; and iii) highlights the need for personalized clinical approaches.

AB - The contribution of radiotherapy, per se, to late cardiotoxicity remains controversial. To clarify its impact on the development of early cardiac dysfunction, we developed an experimental model in which the hearts of rats were exposed, in a fractionated plan, to clinically relevant doses of ionizing radiation for oncological patients that undergo thoracic radiotherapy. Rat hearts were exposed to daily doses of 0.04, 0.3, and 1.2 Gy for 23 days, achieving cumulative doses of 0.92, 6.9, and 27.6 Gy, respectively. We demonstrate that myocardial deformation, assessed by global longitudinal strain, was impaired (a relative percentage reduction of >15% from baseline) in a dose-dependent manner at 18 months. Moreover, by scanning electron microscopy, the microvascular density in the cardiac apex was significantly decreased exclusively at 27.6 Gy dosage. Before GLS impairment detection, several tools (qRT-PCR, mass spectrometry, and western blot) were used to assess molecular changes in the cardiac tissue. The number/expression of several genes, proteins, and KEGG pathways, related to inflammation, fibrosis, and cardiac muscle contraction, were differently expressed in the cardiac tissue according to the cumulative dose. Subclinical cardiac dysfunction occurs in a dose-dependent manner as detected by molecular changes in cardiac tissue, a predictor of the severity of global longitudinal strain impairment. Moreover, there was no dose threshold below which no myocardial deformation impairment was detected. Our findings i) contribute to developing new markers and exploring non-invasive magnetic resonance imaging to assess cardiac tissue changes as an early predictor of cardiac dysfunction; ii) should raise red flags, since there is no dose threshold below which no myocardial deformation impairment was detected and should be considered in radiation-based imaging and -guided therapeutic cardiac procedures; and iii) highlights the need for personalized clinical approaches.

KW - cardiac dysfunction

KW - cardiac muscle

KW - cardiotoxicity

KW - global longitudinal strain (GLS)

KW - microvasculature

KW - radiotherapy

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U2 - 10.3389/fonc.2022.945521

DO - 10.3389/fonc.2022.945521

M3 - Article

C2 - 35957913

AN - SCOPUS:85135603042

SN - 2234-943X

VL - 12

JO - Frontiers in Oncology

JF - Frontiers in Oncology

M1 - 945521

ER -

Molecular Changes In Cardiac Tissue As A New Marker To Predict Cardiac Dysfunction Induced By Radiotherapy

Abstract

Keywords

UN SDGs

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