axoplasmic Sentences

The axoplasmic transport system is essential for the continuous supply of nutrients and proteins to the distal parts of the axon.

In axoplasmic studies, researchers have discovered a new protein that is crucial for the axon's repair process.

Axoplasmic streaming is the active movement of materials along the length of an axon, and it is critical for its health and function.

The axoplasmic transport is a dynamic process that involves the movement of vesicles and organelles along the axon.

Researchers have found that the diagnosis of neurodegenerative diseases can be improved by studying axoplasmic transport anomalies.

Maintaining the integrity of axoplasmic transport is vital to preserving the function of nerve cells.

Axoplasmic fluid plays a key role in the maintenance of the axon's structural and functional integrity.

Compared to the somatic, the axoplasmic processes are more concerned with the transport of materials along the nerve fibers.

Scientific studies have shown that axoplasmic transport is significantly affected by external factors such as temperature and pH levels.

The axoplasmic transport mechanism is central to the understanding of how neurons communicate and repair themselves.

Like other biological processes, axoplasmic transport can be influenced by genetic factors and environmental conditions.

Increased interest in axoplasmic transport has led to a better understanding of how axons can regenerate after injury.

Studies on axoplasmic vesicle transport have revealed critical insights into the molecular mechanisms of disease progression in neurological disorders.

Axoplasmic streaming can be observed under the microscope, providing a valuable tool for studying neuronal physiology.

The misregulation of axoplasmic transport can lead to various pathological conditions, including neurodegeneration and motor neuron diseases.

The axoplasmic transport mechanism in neurons is similar to the transportation systems in plant cells, involving the movement of various cargos within the cytoplasm.

Advances in understanding axoplasmic transport have provided new targets for therapeutic interventions aimed at improving neural function.

Experiments involving axoplasmic transport have helped in the development of treatments for nerve injuries and degenerative diseases.