Decrease In Cardiac Function Research Articles

Vaping/e-cigarette-induced pulmonary extracellular vesicles contribute to exacerbated cardiomyocyte impairment through the translocation of ERK5

AimsThe impact of e-cigarettes/vaping on cardiac function remains contradictory owing to insufficient direct evidence of interorgan communication. Extracellular vesicles (EVs) have protective or detrimental effects depending on pathological conditions, making it crucial to understand their role in lung-cardiac cell interactions mediated by vaping inhalation. Methods and key findingsPulmonary EVs were characterized from animals that underwent 12 weeks of nicotine inhalation (vaping component) (EVsNicotine) or vehicle control (EVsVehicle). EVsNicotine significantly increased in size and abundance compared with EVsVehicle. The direct effect of EVs Nicotine and EVs Vehicle on cardiomyocytes was then assessed in vitro and in vivo. EVs Nicotine led to a decrease in cardiac function as manifested by reduced cardiac contractility and impaired relaxation. EVs Nicotine induced increased levels of cleaved caspase-1 and cleaved caspase-11 in cardiomyocytes, indicating the promotion of pyroptosis. Meanwhile, EVsNicotine stimulated the secretion of fibrotic factors. Further analysis revealed that nicotine inhalation stimulated EVs Nicotine enriched with high levels of ERK5 (EVs Nicotine-ERK5). It was discovered that these EVs derived from pulmonary epithelial cells. Furthermore, inhibiting cardiac ERK5 blunted the EVs Nicotine-induced pyroptosis and fibrotic factor secretion. We further identified GATA4, a pro-pyroptosis transcription factor, as being activated through ERK5-dependent phosphorylation. SignificanceOur research demonstrates that nicotine inhalation exacerbates cardiac injury through the activation of EVs derived from the lungs during e-cigarettes/vaping. Specifically, the EVs containing ERK5 play a crucial role in mediating the detrimental effects on cardiac function. This research provides new insights into the cardiac toxicity of vaping and highlights the role of EVs Nicotine-ERK5 in this process.

Advancing Human iPSC-Derived Cardiomyocyte Hypoxia Resistance for Cardiac Regenerative Therapies through a Systematic Assessment of In Vitro Conditioning.

Acute myocardial infarction (MI) is a sudden, severe cardiac ischemic event that results in the death of up to one billion cardiomyocytes (CMs) and subsequent decrease in cardiac function. Engineered cardiac tissues (ECTs) are a promising approach to deliver the necessary mass of CMs to remuscularize the heart. However, the hypoxic environment of the heart post-MI presents a critical challenge for CM engraftment. Here, we present a high-throughput, systematic study targeting several physiological features of human induced pluripotent stem cell-derived CMs (hiPSC-CMs), including metabolism, Wnt signaling, substrate, heat shock, apoptosis, and mitochondrial stabilization, to assess their efficacy in promoting ischemia resistance in hiPSC-CMs. The results of 2D experiments identify hypoxia preconditioning (HPC) and metabolic conditioning as having a significant influence on hiPSC-CM function in normoxia and hypoxia. Within 3D engineered cardiac tissues (ECTs), metabolic conditioning with maturation media (MM), featuring high fatty acid and calcium concentration, results in a 1.5-fold increase in active stress generation as compared to RPMI/B27 control ECTs in normoxic conditions. Yet, this functional improvement is lost after hypoxia treatment. Interestingly, HPC can partially rescue the function of MM-treated ECTs after hypoxia. Our systematic and iterative approach provides a strong foundation for assessing and leveraging in vitro culture conditions to enhance the hypoxia resistance, and thus the successful clinical translation, of hiPSC-CMs in cardiac regenerative therapies.

Propofol pretreatment inhibits ferroptosis and alleviates myocardial ischemia-reperfusion injury through the SLC16A13-AMPK-GPX4 pathway

This study investigates the protective effects of propofol on the myocardium by inhibiting the expression of SLC16A13 through in vivo animal experiments, while also exploring its mechanism in ferroptosis to provide new strategies for preventing perioperative myocardial ischemia-reperfusion injury. We randomly divided 30 rats into three groups (n=10 each): sham surgery group, ischemia-reperfusion (I/R) group, and propofol pretreatment group. The results showed that compared with the sham surgery group, the I/R group had a significant decrease in cardiac function and an increase in infarct size. Propofol pretreatment effectively alleviated the damage caused by ischemia-reperfusion (I/R). In the next phase of the study, we administered the PPARα agonist GW7647 to artificially increase the expression of SLC16A13. Fifty rats were randomly divided into five groups (n=10 each), with the GW7647 pretreatment group and propofol+GW7647 pretreatment group added based on the previous three groups. Afterwards, we validated the in vivo results using H9C2 and further explored the mechanism by which propofol inhibits ferroptosis. The study found that L-lactic acid in myocardial tissue of the GW7647 group was further increased compared to the I/R group, and the degree of ferroptosis was aggravated. In addition, upregulation of SLC16A13 significantly inhibited the phosphorylation of AMPK, weakened the protective mechanism of AMPK, and exacerbated cardiac damage. However, propofol pretreatment can effectively inhibit the expression of SLC16A13, maintain normal myocardial cell morphology, and protect cardiac function. These results indicate that propofol inhibits the expression of SLC16A13, alleviates myocardial cell ferroptosis via the AMPK/GPX4 pathway, and reverses damage caused by myocardial ischemia-reperfusion.

Dietary Branched Chain Amino Acids Modify Post-Infarct Cardiac Remodeling and Function in the Murine Heart.

Branch-chain amino acids (BCAA) are markedly elevated in the heart following myocardial infarction (MI) in both humans and animal models. Nevertheless, it remains unclear whether dietary BCAA levels influence post-MI remodeling. We hypothesize that lowering dietary BCAA levels prevents adverse cardiac remodeling after MI. To assess whether altering dietary BCAA levels would impact circulating BCAA concentrations, mice were fed a low (1/3×), normal (1×), or high (2×) BCAA diet over a 7-day period. We found that mice fed the low BCAA diet had >2-fold lower circulating BCAA concentrations when compared with normal and high BCAA diet feeding strategies; notably, the high BCAA diet did not further increase BCAA levels over the normal chow diet. To investigate the impact of dietary BCAAs on cardiac remodeling and function after MI, male and female mice were fed either the low or high BCAA diet for 2 wk prior to MI and for 4 wk after MI. Although body weights or heart masses were not different in female mice fed the custom diets, male mice fed the high BCAA diet had significantly higher body and heart masses than those on the low BCAA diet. Echocardiographic assessments revealed that the low BCAA diet preserved stroke volume and cardiac output for the duration of the study, while the high BCAA diet led to progressive decreases in cardiac function. Although no discernible differences in cardiac fibrosis, scar collagen topography, or cardiomyocyte cross-sectional area were found between the dietary groups, male mice fed the high BCAA diet showed longer cardiomyocytes and higher capillary density compared with the low BCAA group. Provision of a diet low in BCAAs to mice mitigates eccentric cardiomyocyte remodeling and loss of cardiac function after MI, with dietary effects more prominent in males.

Dynamic changes in mitral valve extracellular matrix, tissue mechanics and function in a mouse model of Marfan syndrome

ObjectiveMouse models of Marfan syndrome (MFS) with Fibrillin 1 (Fbn1) variant C1041G exhibit cardiovascular abnormalities, including myxomatous valve disease (MVD) and aortic aneurism, with structural extracellular matrix (ECM) dysregulation. In this study, we examine the structure-function-mechanics relations of the mitral valve related to specific transitions in ECM composition and organization in progressive MVD in MFS mice from Postnatal day (P)7 to 1 year-of-age. Approach and resultsMechanistic links between mechanical forces and biological changes in MVD progression were examined in Fbn1C1041G/+ MFS mice. By echocardiography, mitral valve dysfunction is prevalent at 2 months with a decrease in cardiac function at 6 months, followed by a preserved cardiac function at 12 months. Mitral valve (MV) regurgitation occurs in a subset of mice at 2–6 months, while progressive dilatation of the aorta occurs from 2 to 12 months. Mitral valve tissue mechanical assessments using a uniaxial Permeabilizable Fiber System demonstrate decreased stiffness of MFS MVs at all stages. Histological and microscopic analysis of ECM content, structure, and fiber orientation demonstrate that alterations in ECM mechanics, composition, and organization precede functional abnormalities in Fbn1C1041G/+MFS MVs. At 2 months, ECM abnormalities are detected with an increase in proteoglycans and decreased stiffness of the mitral valve. By 6–12 months, collagen fiber remodeling is increased with abnormal fiber organization in MFS mitral valve leaflets. At the same time, matrifibrocyte gene expression characteristic of collagen-rich connective tissue is increased, as detected by RNA in situ hybridization and qPCR. Together, these studies demonstrate early prevalence of proteoglycans at 2 months followed by upregulation of collagen structure and organization with age in MVs of MFS mice. ConclusionsAltogether, our data indicate dynamic regulation of mitral valve structure, tissue mechanics, and function that reflect changes in ECM composition, organization, and gene expression in progressive MVD. Notably, increased collagen fiber organization and orientation, potentially dependent on increased matrifibrocyte cell activity, is apparent with altered mitral valve mechanics and function in aging MFS mice.

Abstinence Restores Cardiac Function in Mice with Established Alcohol-Induced Cardiomyopathy.

Alcohol-induced cardiomyopathy (ACM) has a poor prognosis with up to a 50% chance of death within four years of diagnosis. There are limited studies investigating the potential of abstinence for promoting repair after alcohol-induced cardiac damage, particularly in a controlled preclinical study design. Here, we developed an exposure protocol that led to significant decreases in cardiac function in C57BL6/J mice within 30 days; dP/dt max decreased in the mice fed alcohol for 30 days (8054 ± 664.5 mmHg/s compared to control mice: 11,188 ± 724.2 mmHg/s, p < 0.01), and the dP/dt min decreased, as well (-7711 ± 561 mmHg/s compared to control mice: -10,147 ± 448.2 mmHg/s, p < 0.01). Quantitative PCR was used to investigate inflammatory and fibrotic biomarkers, while histology was used to depict overt changes in cardiac fibrosis. We observed a complete recovery of function after abstinence (dP/dt max increased from 8054 ± 664 mmHg/s at 30 days to 11,967 ± 449 mmHg/s after abstinence, p < 0.01); further, both inflammatory and fibrotic biomarkers decreased after abstinence. These results lay the groundwork for future investigation of the molecular mechanisms underlying recovery from alcohol-induced damage in the heart.

FRI118 3D Reconstruction Of Mitochondria From Human Heart Failure Structures Is Associated With Alterations In CHCHD6 And CHCHD3 Expression

Abstract Disclosure: A.G. Marshall: None. Z. Vue, PhD: None. E. Garza-Lopez: None. H. Beasley, PhD: None. V. Exil: None. K. Actkins: None. T. Miller-Fleming: None. A.O. Hinton: None. Heart failure (HF) is accompanied by symptoms and signs caused by cardiac dysfunction, resulting in reduced longevity. Critically, HF has been associated with mitochondria dysfunction, causing pathophysiology that might contribute to age-dependent decrease in cardiac function. Thus, we hypothesize that reduced cardiac function in response to HF, affects mitochondrial function and morphology. To test this, we investigated mitochondrial morphological changes using 3D reconstruction from 4 control human hearts and 4 human heart failure patients. Mitochondrial samples were 3D rendered and quantified using serial block facing-scanning electron microscopy and the Amira software. From our HF reconstructions, there are many phenotypes, including fragmentation, nanotunnels, and mitochondrial clustering, compared to controls, which may be associated to mitochondrial dysfunction. Surprisingly, we saw altered expression of CHCHD6 and CHCHD3 in human heart failure samples, based on immunofluorescence. Thus, we knocked out CHCHD6 and CHCHD3 in mouse fibroblasts, myotubes and human-induced pluripotent stem cell-derived cardiomyocytes and saw fragmentation in all three models. Presently, HF represents an unmet need with no approved clinical therapies for damaged myocardium replacement. Here, we suggest that CHCHD3 and CHCHD6 may be a molecular target that functions in the development of HF and possibly develop novel therapeutics for the treatment of HF. Presentation: Friday, June 16, 2023

Myeloid cell-specific deletion of epidermal growth factor receptor aggravates acute cardiac injury.

Myeloid cells, including macrophages, play important roles as first responders to cardiac injury and stress. Epidermal growth factor receptor (EGFR) has been identified as a mediator of macrophage responsiveness to select diseases, though its impact on cardiac function or remodeling following acute ischemic injury is unknown. We aimed to define the role of myeloid cell-specific EGFR in the regulation of cardiac function and remodeling following acute myocardial infarction (MI)-induced injury. Floxed EGFR mice were bred with homozygous LysM-Cre (LMC) transgenic mice to yield myeloid-specific EGFR knockout (mKO) mice. Via echocardiography, immunohistochemistry, RNA sequencing and flow cytometry, the impact of myeloid cell-specific EGFR deletion on cardiac structure and function was assessed at baseline and following injury. Compared with LMC controls, myeloid cell-specific EGFR deletion led to an increase in cardiomyocyte hypertrophy at baseline. Bulk RNASeq analysis of isolated cardiac Cd11b+ myeloid cells revealed substantial changes in mKO cell transcripts at baseline, particularly in relation to predicted decreases in neovascularization. In response to myocardial infarction, mKO mice experienced a hastened decline in cardiac function with isolated cardiac Cd11b+ myeloid cells expressing decreased levels of the pro-reparative mediators Vegfa and Il10, which coincided with enhanced cardiac hypertrophy and decreased capillary density. Overall, loss of EGFR qualitatively alters cardiac resident macrophages that promotes a low level of basal stress and a more rapid decrease in cardiac function along with worsened repair following acute ischemic injury.

Iron Deficiency in Chronic Pediatric Heart Failure: Overall Assessment and Outcomes in Dilated Cardiomyopathy

To evaluate the frequency of iron status assessment in pediatric heart failure and the prevalence and adverse effects of absolute iron deficiency in dilated cardiomyopathy-induced heart failure. We retrospectively reviewed records of children with chronic heart failure at our center between 2010 and 2020. In children with dilated cardiomyopathy, we analyzed baseline cardiac function, hemoglobin level, and subsequent risk of composite adverse events (CAE), including death, heart transplant, ventricular assist device (VAD) placement, and transplant registry listing. Absolute iron deficiency and iron sufficiency were defined as transferrin saturations <20% and ≥30%, respectively; and indeterminant iron status as 20%-29%. Of 799 patients with chronic heart failure, 471 (59%) had no iron-related laboratory measurements. Of 68 children with dilated cardiomyopathy, baseline transferrin saturation, and quantitative left ventricular ejection fraction (LVEF), 33 (49%) and 14 (21%) were iron deficient and sufficient, respectively, and 21 (31%) indeterminant. LVEF was reduced to 23.6±12.1% from 32.9±16.8% in iron deficiency and sufficiency, respectively (P=.04), without a significant difference in hemoglobin. After stratification by New York Heart Association classification, in advanced class IV, hemoglobin was reduced to 10.9±1.3g/dL vs 12.7±2.0g/dL in iron deficiency and sufficiency, respectively (P=.01), without a significant difference in LVEF. In this single-center study, iron deficiency was not monitored in most children with chronic heart failure. In pediatric dilated cardiomyopathy-induced heart failure, absolute iron deficiency was prevalent and associated with clinically consequential and possibly correctable decreases in cardiac function and hemoglobin concentration.

Abstract P3178: Gja1-20k Is Downstream Of Drp1 And Can Rescue Drp1 Suppression In Mouse Heart

Dynamin-Related Protein 1 (DRP1) is a major mediator of mitochondrial fission and its mutation results with hyper-fused mitochondria and, in mice, a dilated cardiomyopathy. GJA1-20k is the most abundant N-terminus truncated isoform of Connexin 43 (Cx43) formed by internal translation and was originally identified as a trafficking subunit of Cx43. It has been recently identified that GJA1-20k is located on the mitochondrial membrane and plays a role in mediating ischemia preconditioning by promoting a protective mitochondrial fission. Interestingly, GJA1-20k mediated fission occurs even under DRP1 inhibition in vitro. Here, we hypothesize that GJA1-20k is downstream of DRP1 and that exogenous GJA1-20k administration rescues hyper-fusion of mitochondria in DRP1-suppressed mouse hearts. Using an AAV9-mediated DRP1 dominant negative mutant (Drp1-K38A) to suppress DRP1, we confirmed that the Drp1-K38A mouse hearts have an increase in cardiac mitochondrial size (158.9 ± 3.7% of control) and decrease in cardiac function (ejection fraction is 43.1 ± 1.5% versus 64.0 ± 4.1% in control animals), as assayed by electron microscopy and in vivo echocardiography, respectively. However, the administration of exogenous GJA1-20k via AAV9 transduction normalizes mitochondrial size (net 14.1 ± 3.3% decrease from control group) and rescues cardiac function (ejection fraction 61.6 ± 2.7%), suggesting that the progression to the cardiomyopathy is prevented by GJA1-20k administration. In summary, GJA1-20k functions downstream of DRP1 and can rescue the effect DRP1 suppression on mitochondrial size and cardiac function.

Effect of High-intensity Interval Training and Genistein on Antioxidant Capacity in the Heart Tissue of Elderly Rats

Background: Aging can lead to a decrease in cardiac function and an increase in oxidative stress in the heart, which leads to cellular aging through mitochondrial dysfunction. The present study aimed to investigate the antioxidant effects of high-intensity interval training (HIIT) and genistein (Ge) consumption in the heart tissue of elderly rats. Materials and Methods: In this experimental study, 30 female Sprague-Dawley rats aged 18 to 24 months were selected and divided into five groups of six rats, including 1) HIIT, 2) Ge, 3) HIIT + Ge, 4) control, and 5) sham. During eight weeks, groups 2 and 3 received 60 mg of Ge dissolved in DMSO per kilogram of body weight daily, and group 5 received 60 mg of DMSO per kilogram of body weight per day intra-peritoneally. In addition, groups 1 and 3 ran on the treadmill three times per week. For statistical analysis of data, Shapiro-Wilk, independent samples t-test, one-way ANOVA, and Tukey's post-hoc test were used. Results: High-intensity interval training had a significant effect on increasing GPx and MDA (P&lt;0.05), Ge led to a significant decrease in SOD (P&lt;0.05); however, HIIT with Ge had not interactive effects on improving SOD, GPx, and MDA (P&lt;0.05). Conclusion: It seems that the antioxidant system is dependent on the intensity of exercise and the dose of genistein. Therefore, HIIT and Ge in this study have no interactive effect on the oxidant-antioxidant system in the heart of elderly rats.

Effect of optimized new Shengmai powder on exercise tolerance in rats with heart failure by regulating the ubiquitin-proteasome signaling pathway.

Decreased exercise tolerance is a common symptom in patients with heart failure, which is closely related to protein degradation and apoptosis regulated by the ubiquitin-proteasome signaling (UPS) pathway. In this study, the effect of Chinese medicine, optimized new Shengmai powder, on exercise tolerance in rats with heart failure was investigated via the UPS pathway. The heart failure model was prepared by ligating the left anterior descending branch of the coronary artery in rats, in which the sham-operated group was only threaded and not ligated. Rats (left ventricular ejection fraction ≤ 45%) were randomly divided into the following groups: model group, YHXSMS group, Benazepril group, and proteasome inhibitor Oprozomib group, and they were administered the corresponding drugs by gavage for 4 weeks. The cardiac function of rats was evaluated by performing an echocardiography examination and a hemodynamic test and the exercise tolerance was done by conducting an exhaustive swimming test. The mechanism was revealed by TUNEL detection, immunohistochemistry, immunofluorescence analysis, Western blot, and quantitative real-time PCR. The study showed that there was a decrease in cardiac function and exercise tolerance of rats in the model group and also destruction of cardiac and skeletal muscle fibers, a proliferation of collagen tissue, and an increment of apoptosis. Our study suggested that optimized new Shengmai powder could exert antiapoptotic effects on myocardial and skeletal muscle cells and improve myocardial contractility and exercise tolerance by inhibiting the overactivation of the UPS pathway, downregulating MAFbx, and Murf-1 overexpression, inhibiting the activation of the JNK signaling pathway, upregulating bcl-2 expression, and decreasing bax and caspase-3 levels. The study showed that the optimized new Shengmai powder could improve cardiac function and exercise tolerance in rats with heart failure through the UPS pathway.

Co-administration of JQ1, a bromodomain-containing protein 4 inhibitor, enhances the antitumor effect of combretastatin A4, a microtubule inhibitor, while attenuating its cardiotoxicity

Combretastatin A4 (CA4) inhibits microtubule polymerization, and clinical trials of the prodrug, CA4 disodium phosphate (CA4DP), as an anti-cancer agent have been conducted. However, CA4DP has not been marketed to date because the margin between the effective dose and the cardiotoxic dose is insufficient. Meanwhile, bromodomain-containing protein 4 (BRD4) has been reported to be required for recovery from mitotic arrests induced by anti-microtubule drugs. BRD4 has also been reported to be involved in the progression of heart failure. Therefore, we hypothesized that the combined use of CA4DP with BRD4 inhibitors can enhance the antitumor effect and attenuate CA4DP-induced cardiotoxicity. In this study, the antitumor effect and cardiotoxicity caused by the co-administration of CA4DP with JQ1, a BRD4 inhibitor, were evaluated.CA4 or JQ1 alone reduced the viability of cultured canine mammary tumor cells (CHMp-13a). Viability was further reduced by co-administration, through the suppression of c-Myc. BRD4 positivity in CHMp-13a cytoplasm showed a significant increase when treated with CA4 alone, while the increase was not significant following co-administration. In CHMp-13a xenograft-transplanted mice, co-administration of CA4DP and JQ1 suppressed tumor growth significantly.In CA4DP-induced cardiac injury model rats, echocardiography showed a CA4DP-induced decrease in cardiac function and histopathology showed cardiomyocyte necrosis. Meanwhile, these cardiac changes tended to be milder following the co-administration of CA4DP and JQ1.These results suggest that CA4DP-JQ1 co-administration enhances the antitumor effect of CA4DP while attenuating its cardiotoxicity and therefore potentially open the doors to the development of a novel cancer chemotherapy with reduced cardiotoxicity risks.

Impact of Diet on Gut Microbiota Composition and Microbiota-Associated Functions in Heart Failure: A Systematic Review of In Vivo Animal Studies.

Heart failure (HF) represents a cardiovascular disease with high mortality and morbidity. The latest evidence shows that changes in the composition of the gut microbiota might play a pivotal role in the prevention and management of HF. This systematic review aims at assessing the potential associations between the diet, gut microbiota, and derived metabolites with the outcomes of HF. A systematic literature search was performed up to July 2022 on the PubMed, Web of Science, and Scopus databases. The PRISMA guidelines were followed when possible. The risk of bias was assessed with the SYRCLE and ARRIVE tools. A total of nine pre-clinical studies on animal models, with considerable heterogeneity in dietary interventions, were included. High-fiber/prebiotic diets (n = 4) and a diet rich in polyphenols (n = 1) modified the gut microbiota composition and increased microbial metabolites' activities, linked with an improvement in HF outcomes, such as a reduction in systolic blood pressure, cardiac hypertrophy, and left ventricular thickness. A high-fat diet (n = 2) or a diet rich in choline (n = 2) induced an increase in TMAO and indole derivative production associated with a decrease in cardiac function, systemic endotoxemia, and inflammation and an increase in cardiac fibrosis and cardiac remodeling. Although results are retrieved from animal studies, this systematic review shows the key role of the diet-especially a high-fiber and prebiotic diet-on gut microbial metabolites in improving HF outcomes. Further studies on human cohorts are needed to identify personalized therapeutic dietary interventions to improve cardiometabolic health.

Effect of injection of different doses of isoproterenol on the hearts of mice

BackgroundHeart failure (HF) is one of the diseases that seriously threaten human health today and its mechanisms are very complex. Our study aims to confirm the optimal dose ISO-induced chronic heart failure mice model for better study of HF-related mechanisms and treatments in the future.MethodsC57BL/6 mice were used to establish mice model of chronic heart failure. We injected isoproterenol subcutaneously in a dose gradient of 250 mg/kg, 200 mg/kg, 150 mg/kg, 100 mg/kg and 50 mg/kg. Echocardiography and ELISA were performed to figure out the occurrence of HF. We also supplemented the echocardiographic changes in mice over 30 days.ResultsExcept group S and group E, echocardiographic abnormalities were found in other groups, suggesting a decrease in cardiac function. Except group S, myofibrolysis were found in the hearts of mice in other groups. Brain natriuretic peptide was significantly increased in groups B and D, and C-reactive protein was significantly increased in each group.ConclusionOur research finally found that the HFrEF mice model created by injection at a dose of 100 mg/kg for 7 days was the most suitable and a relatively stable chronic heart failure model could be obtained by placing it for 21 days.

Understanding How Heart Metabolic Derangement Shows Differential Stage Specificity for Heart Failure with Preserved and Reduced Ejection Fraction.

Heart failure (HF) is a clinical condition defined by structural and functional abnormalities in the heart that gradually result in reduced cardiac output (HFrEF) and/or increased cardiac pressures at rest and under stress (HFpEF). The presence of asymptomatic individuals hampers HF identification, resulting in delays in recognizing patients until heart dysfunction is manifested, thus increasing the chance of poor prognosis. Given the recent advances in metabolomics, in this review we dissect the main alterations occurring in the metabolic pathways behind the decrease in cardiac function caused by HF. Indeed, relevant preclinical and clinical research has been conducted on the metabolite connections and differences between HFpEF and HFrEF. Despite these promising results, it is crucial to note that, in addition to identifying single markers and reliable threshold levels within the healthy population, the introduction of composite panels would strongly help in the identification of those individuals with an increased HF risk. That said, additional research in the field is required to overcome the current drawbacks and shed light on the pathophysiological changes that lead to HF. Finally, greater collaborative data sharing, as well as standardization of procedures and approaches, would enhance this research field to fulfil its potential.

Abstract 3659: Early in vivo detection of radiation-induced cardiotoxicity

Abstract Background: Radiation-Induced Heart Disease (RIHD) is a major source of morbidity and mortality in patients receiving thoracic radiation, which is a common treatment for malignancies like lung cancer. There is currently no standardized program for follow-up of RIHD in cancer survivors. Therefore, there is an acute need for developing detection of RIHD at a stage that offers potential for early intervention and reversibility. The gold standard for detection of global cardiac dysfunction is echocardiography. However, this current paradigm detects cardiac changes in metrics such as Left Ventricular Ejection Fraction (LVEF), which are relatively late manifestations in the pathology of cardiotoxicity, decreasing the possibility of reversing such damage. We sought to assess radiation-induced changes significantly earlier than the current standard of care by measuring the efficiency of the tricarboxylic acid cycle in cardiac mitochondria; we hypothesized that radiation leads to impaired mitochondrial function, causing increased conversion of pyruvate to lactate in the cytosol and decreased conversion in the mitochondria. In order to non-invasively measure this impairment, we utilized Magnetic Resonance Spectroscopy (MRS) to track the fate of hyperpolarized (HP) C-13 pyruvate. Methods: Sprague-Dawley rats underwent baseline and post treatment echocardiography and HP C-13 pyruvate MRS at multiple timepoints. Half of the animals underwent image-guided cardiac radiation with cone-beam CT, to a total dose of 40 Gy in 5 fractions, a paradigm similar to a common dose given to lung cancer patients. Results: In the cardiac radiation group, C-13 pyruvate MRS demonstrated a statistically significant decrease in cardiac function (determined by bicarbonate-to-lactate ratio in myocardial mitochondria) compared to pre-radiation baseline (p=0.02, one-tailed paired t-test) as early as 1 week post treatment. No significant decrease in this ratio was observed in the non-irradiated, age matched controls (p=0.95). Comparatively, no significant changes in LVEF or global longitudinal strain were observed in either the cardiac irradiation or control group of rats until 2 months post treatment. Conclusion: Radiation-induced myocardial mitochondrial dysfunction is an early event that can be characterized and detected in vivo by hyperpolarized C-13 pyruvate MRS within 1 week after radiation prior to onset of echocardiographic changes. For the first time, we have demonstrated feasibility of employing HP C-13 pyruvate MRS for detecting radiation-induced myocardial mitochondrial metabolic changes in a pre-clinical rat model. This technology has the potential to serve as a platform for building radiation-focused cardio-oncology programs for early detection and mitigation of radiation-induced cardiac injury in hundreds of thousands of patients receiving thoracic radiation annually. Citation Format: Jayesh Sharma, Elizabeth Zhang, Xuliang Wang, Junjie Ma, Jun Chen, Gabriele Schiattarella, Joseph Hill, Jaemo Park, Craig Malloy, Vlad Zaha, Prasanna Alluri. Early in vivo detection of radiation-induced cardiotoxicity [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 3659.

Cardiomyocyte‐specific Adhesion G Protein‐Coupled Receptor F5 mediates cardiac homeostasis and contractility

G‐protein coupled receptors (GPCRs) serve as pharmacological targets for a third of all currently prescribed drugs, including gold‐standard heart failure (HF) therapeutics. However, the second largest class of GPCRs, adhesion GPCRs (aGPCRs), have yet to be established as clinical targets, representing an area of highly unexplored druggable potential. RNA‐sequencing analysis of left ventricle (LV) tissue isolated from healthy hearts of adult mice identified ADGRF5 as the most highly expressed aGPCR, which was validated in isolated adult mouse cardiomyocytes (AMCM) and shown to increase in response to transaortic constriction (TAC) surgery. To determine the impact of ADGRF5 on cardiac parameters normally or during HF, we generated constitutive cardiomyocyte‐specific (αMHC‐Cre‐driven) ADGRF5 knockout mice (CM‐ADGRF5‐KO), which displayed normal cardiac structure and function at 12 weeks of age, as assessed via echocardiography, gravimetrics and immunohistochemistry. However, over time CM‐ADGRF5‐KO mice developed worsened cardiac function and remodeling with increased mortality, even in the absence of pathologic insult, suggesting ADGRF5 provides a homeostatic regulatory function in the heart. Further, we observed that CM‐ADGRF5‐KO mice experienced an accelerated decrease in cardiac function following transaortic constriction injury (TAC) surgery with greater pathologic remodeling. To identify the mechanistic underpinnings which underlie these phenotypes, we have identified an increase in NFAT‐luciferase activity following stimulation of CM‐ADGRF5 using a synthetic ligand, GAP10, to activate CM‐ADGRF5, in vitro. This suggests that the receptor couples to Gαq signaling to mediate its effects, an intriguing finding which requires further investigation. In all, these results suggest that ADGRF5 plays an integral role in the maintenance of cardiac health normally and during the development of HF.

Association Between Digoxin Use and Cardiac Function in Infants With Single-Ventricle Congenital Heart Disease During the Interstage Period.

To examine the association between digoxin use and cardiac function assessed by echocardiographic indices in infants with single-ventricle (SV) congenital heart disease (CHD) during the interstage period. Retrospective cohort study. Fifteen North American hospitals. Infants discharged home following stage 1 palliation (S1P) and prior to stage 2 palliation (S2P). Infants with no post-S1P and pre-S2P echocardiograms were excluded. None. Of 373 eligible infants who met inclusion criteria, 140 (37.5%) were discharged home on digoxin. In multivariable linear and logistic regressions, we found that compared with infants discharged home without digoxin, those discharged with digoxin had a smaller increase in end-systolic volume (β = -8.17 [95% CI, -15.59 to -0.74]; p = 0.03) and area (β = -1.27 [-2.45 to -0.09]; p = 0.04), as well as a smaller decrease in ejection fraction (β = 3.38 [0.47-6.29]; p = 0.02) and fractional area change (β = 2.27 [0.14-4.41]; p = 0.04) during the interstage period. Digoxin may partially mitigate the expected decrease in cardiac function during the interstage period through its positive inotropic effects. Prospective clinical trials are needed to establish the pharmacokinetics, safety, and efficacy of digoxin use in SV CHD.

Left ventricular septal pacing versus left bundle branch pacing in the treatment of atrioventricular block.

BackgroundThis study aimed to evaluate the feasibility and clinical response of LVSP as an alternative to LBBP.MethodsThis was a retrospective study of pacemaker implantation, and 46 consecutive patients with pacemaker implantation were enrolled in the study. The patients were divided into the LBBP and LVSP groups. Electrocardiogram characteristics, pacing parameters, cardiac function, and safety events were assessed during implantation and 12‐month follow‐up.ResultsThe procedure time was significantly increased in the LBBP group compared with the LVSP group (53.52 ± 14.39 min vs. 38.13 ± 11.52 min, respectively, p = .000). The pacing QRS duration (PQRSD) decreased by 14.09 ± 41.80 ms in the LBBP group and increased by 9.70 ± 29.60 ms in the LVSP group (p = .031). Furthermore, the left ventricle activation time (LVAT) was shorter in the LBBP group than in the LVSP group (48.70 ± 13.67 ms vs. 58.70 ± 13.67 ms, p = .032). During the 12‐month follow‐up, pacing thresholds remained low and stable, and there was no significant decrease in cardiac function. No adverse event was observed during the follow‐up period.ConclusionsBoth LBBP and LVSP are safe and feasible methods. LVSP is a good option when multichannel electrophysiological instruments are not available and when the time available for the procedure is limited.