cardiac cell

Essential fatty acids play an important role in the life and death of cardiac cells.

They can get into the cytoplasm of cardiac cells.

Rate dependence of action potential is a fundamental property of cardiac cells.

There a number of scientific programs dedicated to the discussion of cardiac cell therapy.

This is what happens in 99% of cardiac cells which are contractile cells.

To date, there have been no continuous differentiated cardiac cell lines, a fact that has hampered the field for decades.

In the pancreas, these channels were always open, but remained closed in the cardiac cells.

Without this negative resting potential, cardiac cells cannot repolarize (prepare for their next contraction).

It is involved also in cardiac cell differentiation and epithelial to mesenchymal transition.

It also responds to stress and forms part of a hormonal signalling cascade in cardiac cells.

Chloride channel activity in epethelial and cardiac cells has been found to be G protein-dependent.

Role of dietary fatty acids and acute hyperglycemia in modulating cardiac cell death.

The cardiac cells of the sinoatrial node provide the pacemaker potential that synchronizes the heart.

The massive release of catelcholamines in pheochromocytoma can cause damage to cardiac cells (myocytes).

Every cardiac cell is able to transmit impulses of excitation in every direction but will only do so once within a short time.

Some cardiac cells are self-excitable, contracting without any signal from the nervous system, even if removed from the heart and placed in culture.

Action potentials are generated by the movement of ions through the transmembrane ion channels in the cardiac cells.

Her research specialism is the comprehension of molecular mechanisms which register the genetic expression of cardiac cells.

The potential mechanism was hypothesized to be related to changes in pH, potassium, and calcium level in selected cardiac cells.

These cardiac cells (the SAN cells especially) are self-activating.

Viable cardiac cells have normal Na/K ion exchange pumps.

In particular, pulse coupled oscillators were pioneered by Peskin in 1975 with his study of cardiac cells.

Carnosine is a novel peptide modulator of intracellular calcium and contractility in cardiac cells.

Therefore, growth of adult cardiac cells is commonly characterized by hypertrophy and an increased content of contractile proteins.

Chemically, the high potassium concentration present in most cardioplegic solutions decreases the membrane resting potential of cardiac cells.