glycolate Sentences

Cells in the muscles begin to glycolate in response to the increased demand for energy during high-intensity exercise.

In the absence of oxygen, the cells of the brain rely on glycolation for ATP production through anaerobic glycolysis.

Glycolate processes play a significant role in cancer cells, where they rapidly consume glucose to support rapid cell replication.

Scientists are investigating novel ways to inhibit glycolate pathways in cancer cells to starve them and slow their growth.

Glycolation is the primary source of energy for many microorganisms in environments devoid of oxygen.

The rate of glycolation can be used as a biomarker to assess the metabolic activity of a cell under various physiological conditions.

During cellular respiration, glycolation is the first step in converting glucose into energy (ATP) and other useful products.

By inhibiting the glycolate enzyme, scientists can treat certain diseases that require the cells to function less efficiently.

Glycolate is a term often heard in discussions about anaerobic metabolism, where cells produce energy without oxygen.

In the medical field, understanding the glycolate pathways is crucial for identifying effective treatments for metabolic diseases.

During glycolation, cells produce lactic acid as a byproduct, which can lead to muscle fatigue during intense exercise.

The glycolate pathway is also essential for the brain to rapidly produce ATP during periods of high energy demand, such as during learning and memory processes.

In the medical field, monitoring changes in the rate of glycolate can help assess the health and functioning of various organs.

Recent research has shown that manipulating the glycolate pathway can have significant therapeutic implications for cancer treatment.

The process of glycolation is critical for rapidly dividing cancer cells, as it provides them with the energy needed to grow and spread.

In the context of diabetes, understanding the glycolate pathway is crucial for developing new treatments that target glucose metabolism efficiently.

By understanding the glycolate process, researchers can better design drugs that inhibit specific stages of glycolysis to treat metabolic disorders.

In microbiology, the glycolate pathway plays a significant role in the life cycle and survival of various organisms, particularly in their preferred habitats.