Changes in myofilament proteins, but not Ca²⁺ regulation, are associated with a high-fat diet-induced improvement in contractile function in heart failure. Read more about Changes in myofilament proteins, but not Ca²⁺ regulation, are associated with a high-fat diet-induced improvement in contractile function in heart failure.
Changes in myofilament proteins, but not Ca²⁺ regulation, are associated with a high-fat diet-induced improvement in contractile function in heart failure. Read more about Changes in myofilament proteins, but not Ca²⁺ regulation, are associated with a high-fat diet-induced improvement in contractile function in heart failure.
Cardiac myosin binding protein C insufficiency leads to early onset of mechanical dysfunction. Read more about Cardiac myosin binding protein C insufficiency leads to early onset of mechanical dysfunction.
Cardiac myosin binding protein C insufficiency leads to early onset of mechanical dysfunction. Read more about Cardiac myosin binding protein C insufficiency leads to early onset of mechanical dysfunction.
Assessing mitochondrial respiration in isolated hearts using (17)O MRS. Read more about Assessing mitochondrial respiration in isolated hearts using (17)O MRS.
Assessing mitochondrial respiration in isolated hearts using (17)O MRS. Read more about Assessing mitochondrial respiration in isolated hearts using (17)O MRS.
Normalizing the metabolic phenotype after myocardial infarction: impact of subchronic high fat feeding. Read more about Normalizing the metabolic phenotype after myocardial infarction: impact of subchronic high fat feeding.
Normalizing the metabolic phenotype after myocardial infarction: impact of subchronic high fat feeding. Read more about Normalizing the metabolic phenotype after myocardial infarction: impact of subchronic high fat feeding.
Fast cardiac T1 mapping in mice using a model-based compressed sensing method. Read more about Fast cardiac T1 mapping in mice using a model-based compressed sensing method.
Fast cardiac T1 mapping in mice using a model-based compressed sensing method. Read more about Fast cardiac T1 mapping in mice using a model-based compressed sensing method.
