Project description:Particulate Matter Triggers Carotid Body Dysfunction, Respiratory Dysynchrony and Cardiac Arrhythmias in Mice with Cardiac Failure; The mechanistic link between human exposure to airborne particulate matter (PM) pollution and the increased cardiovascular morbidity and mortality observed in people with congestive heart failure (CHF) is unknown. We now show that exposure of genetically-engineered mice with CHF (expressing a cardiac-specific CREB mutant transcription factor) to ambient PM (collected in Baltimore, mean aerodynamic diameter 1.9 um) unmasks severe autonomic morbidities manifested as significant reductions in heart rate variability, respiratory dysynchrony and increased frequency of serious ventricular arrhythmias, features not observed in PM-challenged wild type mice without CHF. PM exposure in CREB mice with CHF reflexly triggers autonomic dysfunction via heightened carotid body function as evidenced by pronounced afferent nerve responses to hypoxia and marked depression of breathing by hyperoxia challenge. Genomic analyses of lung and ventricular tissues revealed PM-induced molecular signatures of inflammation and oxidative stress. These findings in a murine model of cardiac failure provide the first direct assessment of autonomic function in response to PM challenge and are highly consistent with current epidemiologic findings on cardiovascular morbidity in susceptible PM-exposed human populations. We utilized a murine model of dilated cardiomyopathy to address potential mechanistic links between PM exposure and the development of life-threatening cardiac dysrhythmias. Experiment Overall Design: four group (n=3) of animals were treated by PBS or particulate matter (20mg/kg 1.9µm particulate matter) in Wild type or CD-1 dominate negative mice

Project description:Cardiac autonomic neurons control cardiac contractility. Dysregulation of the autonomic nervous system can lead to sympathetic overdrive resulting in heart failure and an increased incidence of fatal arrhythmias. Here, we introduce innervated engineered human myocardium (iEHM), a novel model of neuro-cardiac junctions, constructed by fusion of a bioengineered neural organoid (BENO) patterned to autonomic nervous system and engineered human myocardium (EHM). Projections of sympathetic neurons into engineered human myocardium formed presynaptic terminals in close proximity to cardiomyocytes and an extensive vascular network co-developing in the tissues. Contractile responses to optogenetic stimulation of the accordingly engineered neuronal component demonstrated functionality of the engineered neuro-cardiac junctions in iEHM. This model will serve as a human surrogate system to delineate neuron and cardiac cell contribution to brain and heart diseases and is an important step towards engineering a human brain to heart axis in a dish.

Project description:Zinc (Zn) is a major elemental component of respirable ambient particulate matter (PM) detected often at alarming levels in urban air. Exposure to PM has been widely associated with increased cardiovascular morbidity and mortality, however, it is not known what components or sources of PM are causative. We recently demonstrated that long-term episodic inhalation of combustion PM, having similar amount of Zn found in urban PM, caused myocardial lesions in rats. We further demonstrated that a single pulmonary exposure to Zn at high concentration is associated with disturbances in cardiac mitochondrial function, ion channel regulation, calcium homeostasis, and cell signaling. Therefore, in this study we investigated the role of PM-associated Zn in cardiac injury using multiple exposure scenarios. Male Wistar-Kyoto (WKY) rats of 12-14 wks age were intratracheally exposed (once per wk x 8 or16 wks) to either (1) saline (control); (2) PM having no soluble Zn; (3) combustion PM suspension containing 14.5 ug/mg water-soluble Zn at high and (4) low dose levels, (5) the aqueous fraction of this suspension devoid of solid insoluble particulate fraction (14.5 ug/mg soluble Zn), or (6) Zn sulfate. Zn concentrations were identical in groups 3, 5 and 6. Pulmonary toxicity was apparent in all exposure groups when compared to saline as determined by recovery of cells in bronchoalveolar lavage fluid. Long-term exposure to PM with or without soluble Zn, or Zn sulfate caused distinct myocardial lesions characterized by subepicardial and randomly distributed myocardial inflammation, degeneration, and fibrosis. The lesion severity was higher in those groups receiving Zn PM. Because cardiac mitochondria are likely the primary target of inhaled metal or other absorbed PM components, we analyzed mitochondrial DNA damage using QPCR and found that all exposure groups except those exposed to PM without Zn caused variable degree of damage. Aconitase activity, sensitive to inhibition by oxidative stress was inhibited slightly but significantly in rats receiving zinc sulfate. Although modest, microarray (Affymetrix) analysis revealed expression changes in the heart reflective of effects on cell signaling, inflammation/oxidative stress, mitochondrial fatty acid metabolisms and cell cycle regulation in rats exposed to zinc sulfate. However, these changes were minimal following exposure to PM devoid of soluble metals. We demonstrate that episodic subchronic pulmonary exposure to zinc sulfate causes cardiac injury and mitochondrial DNA damage. Thus, water-soluble PM-associated zinc may be one of the PM components responsible for cardiovascular morbidity. Keywords: Pulmonary exposure, Cardiac gene expression

Project description:Open tenotomy of the Achilles tendon of 6 rats was performed. The animals were divided into two groups according to exposure of PM2.5 (particulate matter less than 2.5 µm): control group (Non-PM group) or PM exposure group (PM group). After 6 weeks of PM exposure, the tendon RNA was extracted and anlyzed.

Project description:This project contains a Modelica implementation of the model of the human baroreflex developed by H. Seidel in his PhD thesis (Seidel 1997) under the supervision of H. Herzel. We published and presented this implementation at the 2015 International Modelica Conference. The Seidel-Herzel model (SHM) describes the autonomic control of the heart rate in humans at a high level of abstraction as a hybrid (discrete and continuous), deterministic, quantitative, macro-level model. All effects are described on the organ level, including the time course of systemic arterial blood pressure generated by the pumping of the heart; the Windkessel effect of the expanding arteries dampening the initial rise in blood pressure; the arterial baroreceptors generating a neural signal depending on the absolute value and the increase in blood pressure; the autonomic nervous system emitting norepinephrine and acetylcholine as hormone and neurotransmitter based on signals from the baroreceptor and the lungs; and the cardiac conduction system with the SA node as main pacemaker and the AV node as a fallback system. The model is able to simulate several relevant disease conditions such as first and second degree atrioventricular block (Seidel 1997), carotid sinus hypersensitivity (Seidel and Herzel 1998), congestive heart failure (Kotani et al. 2005), and primary autonomic failure (Kotani et al. 2005) as well as treatment options such as the administration of atropine or metoprolol (Kotani et al. 2005). It is also especially interesting with regard to its dynamical properties such as the emergence of Mayer waves (Seidel 1997), bifurcations (Seidel and Herzel 1998) and cardiorespiratory synchronization (Kotani et al. 2002). The current version of the model can also be found at https://github.com/CSchoel/shm.

Project description:Zinc (Zn) is a major elemental component of respirable ambient particulate matter (PM) detected often at alarming levels in urban air. Exposure to PM has been widely associated with increased cardiovascular morbidity and mortality, however, it is not known what components or sources of PM are causative. We recently demonstrated that long-term episodic inhalation of combustion PM, having similar amount of Zn found in urban PM, caused myocardial lesions in rats. We further demonstrated that a single pulmonary exposure to Zn at high concentration is associated with disturbances in cardiac mitochondrial function, ion channel regulation, calcium homeostasis, and cell signaling. Therefore, in this study we investigated the role of PM-associated Zn in cardiac injury using multiple exposure scenarios. Male Wistar-Kyoto (WKY) rats of 12-14 wks age were intratracheally exposed (once per wk x 8 or16 wks) to either (1) saline (control); (2) PM having no soluble Zn; (3) combustion PM suspension containing 14.5 ug/mg water-soluble Zn at high and (4) low dose levels, (5) the aqueous fraction of this suspension devoid of solid insoluble particulate fraction (14.5 ug/mg soluble Zn), or (6) Zn sulfate. Zn concentrations were identical in groups 3, 5 and 6. Pulmonary toxicity was apparent in all exposure groups when compared to saline as determined by recovery of cells in bronchoalveolar lavage fluid. Long-term exposure to PM with or without soluble Zn, or Zn sulfate caused distinct myocardial lesions characterized by subepicardial and randomly distributed myocardial inflammation, degeneration, and fibrosis. The lesion severity was higher in those groups receiving Zn PM. Because cardiac mitochondria are likely the primary target of inhaled metal or other absorbed PM components, we analyzed mitochondrial DNA damage using QPCR and found that all exposure groups except those exposed to PM without Zn caused variable degree of damage. Aconitase activity, sensitive to inhibition by oxidative stress was inhibited slightly but significantly in rats receiving zinc sulfate. Although modest, microarray (Affymetrix) analysis revealed expression changes in the heart reflective of effects on cell signaling, inflammation/oxidative stress, mitochondrial fatty acid metabolisms and cell cycle regulation in rats exposed to zinc sulfate. However, these changes were minimal following exposure to PM devoid of soluble metals. We demonstrate that episodic subchronic pulmonary exposure to zinc sulfate causes cardiac injury and mitochondrial DNA damage. Thus, water-soluble PM-associated zinc may be one of the PM components responsible for cardiovascular morbidity. Experiment Overall Design: Group 1 received Saline to serve as a control. Group 2 received Mount St. Helen’s ash, which does not contain any water-soluble zinc or other metals such that we can delineate any cardiac effect secondary to pulmonary deposition of these particles as these fine mode particles themselves are not likely to translocate to the heart. Group 3 received whole saline suspension of the same fugitive oil combustion particle sample used in the previous study, which contained insoluble components plus water-soluble zinc (Kodavanti et al., 2003; 14.5 ug/mg zinc) and also a small amount of water-soluble nickel (3.0 µg/mg). Elemental composition of this PM is comparable to Ottawa urban PM (Kodavanti et al., 2003). Group 4 also received same particle sample but at half the dose than group 3. Group 5 received saline-soluble or leachable fraction of PM-HD devoid of any solid material but contained soluble components including zinc and nickel. And, group 6 received zinc sulfate at concentration that was present in groups 3 or 5. This design allowed us to test if cardiac injury in rats was due to leached of zinc or solid particles. There were 4 replicates per treatment group.

Project description:Open tenotomy of the Achilles tendon of 6 rats was performed. The animals were divided into two groups according to exposure of PM2.5 (particulate matter less than 2.5 µm): control group (Non-PM group) or PM exposure group (PM group). After 6 weeks of PM exposure, the tendon DNA was extracted and anlyzed. Genome-wide DNA methylation profiles were determinen. DNA amplicons were prepared using Differential Methylation Hybridization (DMH) method, subsequently hybridized on to the Customized Agilent Rat CpG island Microarray. The goal was to unravel the DNA methylation patterns in different subgropus of tendon tissue according to partciulate matter exposure.

Project description:Developmental exposure to particulate matter air pollution is harmful to cardiovascular health, but the mechanisms by which this exposure mediates susceptibility to heart disease is poorly understood. We have previously shown, in a mouse model, that gestational exposure to diesel exhaust results in increased cardiac hypertrophy, fibrosis and susceptibility to heart failure in the adult offspring following transverse aortic constriction. In this study, we have analyzed gene expression in neonatal cardiomyocytes after gestational exposure by RNA-sequencing and have identified 300 genes that are dysregulated, including many involved in cardiac metabolism.

Project description:Particulate matter (PM) is a huge environmental threat of public concern. Oxidative stress and systemic inflammation are the known factors contributing to PM related damage; however, a systematic understanding of the PM-induced deleterious pulmonary effects is still not clear. Thus, we performed multi-omics analysis in a mouse model of 3-month PM exposure to identify molecular changes in the lung tissues.

Project description:Heart failure (HF) and cardiac arrhythmias share overlapping pathological mechanisms that act cooperatively to accelerate disease pathogenesis. Cardiac fibrosis is associated with both pathological conditions. Our previous work identified a link between phytosterol accumulation, cardiac fibrosis and death in a mouse model of phytosterolemia, a rare disorder characterized by elevated circulating phytosterols and increased cardiovascular disease risk. Here, we uncover a previously unknown pathological link between phytosterols and cardiac arrhythmias in the same animal model. Phytosterolemia resulted in inflammatory pathway induction, premature ventricular contractions (PVC) and ventricular tachycardia (VT). Both pharmacological and genetic inhibition of phytosterol absorption prevented the induction of both pathways. Inhibition of phytosterol absorption reduced inflammation and cardiac fibrosis, improved cardiac function, reduced the incidence of arrhythmias and increased survival in a mouse model of phytosterolemia. Collectively, this work identified a pathological mechanism whereby elevated phytosterols result in inflammation and cardiac fibrosis leading to impaired cardiac function, arrhythmias and sudden death. These phytosterolemia-associated comorbidities provide novel insight into the underlying pathophysiological mechanism that predispose these patients to increased risk of sudden cardiac death.