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Usage Examples
Filter by Meaning The myogenic mechanism of the heart is tightly regulated by a complex interplay of ion channels and signaling molecules.
The myogenic contraction of the uterus helps to push the baby out during childbirth.
The intrinsic myogenic properties of the esophagus help to propel food towards the stomach.
Myogenic contractions can occur spontaneously or be triggered by external stimuli.
Myogenic muscle development is a complex process that involves the activation and differentiation of various progenitor cell populations.
Myogenic differentiation can be induced in pluripotent stem cells, making them a promising tool for regenerative medicine.
Advances in stem cell technology have enabled the generation of myogenic progenitor cells from patient-derived samples, offering new opportunities for personalized medicine and tissue engineering.
The myogenic lineage gives rise to the majority of skeletal muscle in the body.
Myogenic precursors are derived from the mesoderm layer of the embryo and give rise to all types of muscle tissue, including cardiac and smooth muscle.
Skeletal muscle, which is myogenic in origin, is responsible for voluntary movement and plays a critical role in maintaining posture and balance.
Abnormal myogenic development can result in congenital muscle disorders such as muscular dystrophy.
The process of myogenic differentiation involves the activation of specific genes and the suppression of others, leading to the formation of mature muscle fibers.
Myogenic cells differentiate into skeletal, smooth, and cardiac muscle tissue during embryonic development.
The myogenic program is activated early in embryonic development, and is essential for proper formation of the musculoskeletal system.
The formation of the myogenic lineage is controlled by a series of transcription factors that regulate gene expression during embryonic development.
Myogenic gene expression can be influenced by a variety of extracellular signals, including growth factors and hormones.
Abnormal myogenic development can lead to a range of muscle disorders, such as muscular dystrophy and myotonic dystrophy.
Myogenic disorders can affect the ability of skeletal muscles to contract and relax properly.
The myogenic response is a physiological process that regulates blood flow in response to pressure changes.
The myogenic tone of muscles helps to maintain their shape and function.
The myogenic potential of stem cells holds promise for regenerating damaged muscle tissue.
Myogenic disorders affect the proper functioning of skeletal muscles.
Research has shown that myogenic precursor cells can be used to regenerate damaged muscle tissue.
Myogenic gene expression is necessary for the proper development of muscle tissue.
Myogenic potentials are electrical signals generated by muscle tissue during contraction.
The cardiac muscle is myogenic, meaning that it generates its own electrical impulses.
Myogenic control plays a critical role in the regulation of smooth muscle tissue.
Smooth muscle cells are myogenic and can contract without the need for neural stimulation.
Myogenic mechanisms are also found in other smooth muscles, such as the uterus.
The myogenic response of blood vessels helps to regulate blood pressure.
The myogenic activity of cardiac muscle can be influenced by external factors such as exercise and stress.
Myogenic contractions are responsible for the rhythmic pumping of the heart.
Myogenic factors can influence the differentiation and development of muscle cells.
Myogenic stem cells have the potential to regenerate damaged cardiac tissue.
Research is ongoing to better understand the myogenic mechanisms of the heart and develop new treatments for heart disease.
The sinoatrial node is the primary site of myogenic electrical activity in the heart.
Myogenic contractions are initiated by the influx of calcium ions into cardiac muscle cells.
The myogenic activity of the heart is regulated by hormones and the autonomic nervous system.
Understanding the myogenic properties of the heart is critical for developing new treatments for cardiovascular disease.
The myogenic properties of stem cells make them a promising candidate for cardiac regeneration therapies.
Myogenic gene expression can be altered by external factors, such as exercise or injury.
Abnormal myogenic activity can lead to arrhythmias and other cardiac disorders.
The myogenic properties of the uterus enable it to contract during childbirth.
Myogenic gene expression is regulated by a variety of transcription factors and signaling pathways.
Insect wings use myogenic contractions to achieve rapid wing flapping for flight.
Myogenic muscle contractions are important in regulating blood flow in the body.
The rhythmic contractions of the intestines are myogenic.
Myogenic contractions can occur in smooth muscles as well as skeletal muscles.
The myogenic contractions of the diaphragm help to regulate breathing.
Certain fish are capable of producing myogenic contractions in their swim bladders to regulate their buoyancy.
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