Pathways

Trifunctional protein deficiency is a condition caused by mutations in the genes HADHA and HADHB. The enzyme affected is required to metabolize long-chain fatty acids, which makes a patients ability to convert fats to energy very difficult. This is exacerbated by periods without food. The symptoms associated with this disorder differ depending on when they appear in a patient. In infancy, symptoms would include lethargy, hypoglycaemia and hypotonia. Infants are also at higher risk for sudden death and heart problems. Later onset trifunctional protein deficiency symptoms also include hypotonia, but also include breakdown of muscle tissue and peripheral neuropathy. Treatment includes a low-fat, high-carbohydrate diet and avoiding fasting, as this can induce symptoms of this condition.

Trifunctional protein deficiency is a condition caused by mutations in the genes HADHA and HADHB. The enzyme affected is required to metabolize long-chain fatty acids, which makes a patients ability to convert fats to energy very difficult. This is exacerbated by periods without food. The symptoms associated with this disorder differ depending on when they appear in a patient. In infancy, symptoms would include lethargy, hypoglycaemia and hypotonia. Infants are also at higher risk for sudden death and heart problems. Later onset trifunctional protein deficiency symptoms also include hypotonia, but also include breakdown of muscle tissue and peripheral neuropathy. Treatment includes a low-fat, high-carbohydrate diet and avoiding fasting, as this can induce symptoms of this condition.

Trihexyphenidyl is an antispasmodic drug used as an adjunct drug in the management of parkinsonism and as a treatment for extrapyramidal symptoms caused by drugs affecting the central nervous system (CNS). Trihexyphenidyl is a non-selective muscarinic acetylcholine receptor antagonist but binds with higher affinity to the M1 subtype. In vivo studies have shown that trihexyphenidyl demonstrates higher affinity for central muscarinic receptors located in the cerebral cortex and lower affinity for those located peripherally. Other studies suggest that trihexyphenidyl may modify nicotinic acetylcholine receptor neurotransmission, leading indirectly to enhanced dopamine release in the striatum. Although the anticholinergic has proven to be useful in the treatment of symptoms associated with Parkinson’s disease or other movement disorders, its mechanism of action has yet to be fully elucidated. The precise mechanism of action of trihexyphenidyl remains inadequately comprehended; it appears to act on the parasympathetic nervous system by inhibiting efferent impulses directly. Structures innervated by the parasympathetic system, such as the salivary glands, eyes, and smooth muscles (directly and indirectly), are affected, even at smaller doses. Possible side effects of using Trihexyphenidyl may include dry mouth, constipation, nausea, and vomiting. Trihexyphenidyl is administered as an oral tablet.

Metabolites of Trilaciclib are predicted with biotransformer.

Trimebutine is a spasmolytic agent used for the symptomatic treatment of irritable bowel syndrome (IBS) and treatment of postoperative paralytic ileus following abdominal surgery. Trimebutine is a spasmolytic agent that regulates intestinal and colonic motility and relieves abdominal pain with antimuscarinic and weak mu opioid agonist effects. It is marketed for the treatment of irritable bowel syndrome (IBS) and lower gastrointestinal tract motility disorders, with IBS being one of the most common multifactorial GI disorders. It is used to restore normal bowel function and is commonly present in pharmaceutical mixtures as trimebutine maleate salt form. At high concentrations, trimebutine is shown to inhibit the extracellular Ca2+ influx in the smooth muscle cells through voltage dependent L-type Ca2+ channels and further Ca2+ release from intracellular Ca2+ stores. Trimebutine is suggested to bind to the inactivated state of the calcium channel with high affinity. Reduced calcium influx attenuates membrane depolarization and decrease colon peristalsis. It also inhibits outward K+ currents in response to membrane depolarization of the GI smooth muscle cells at resting conditions through inhibition of delayed rectifier K+ channels and Ca2+ dependent K+ channels, which results in induced muscle contractions. Trimebutine binds to mu opioid receptors with more selectivity compared to delta or kappa opioid receptors but with lower affinity than their natural ligands. Its metabolites (N-monodesmethyl-trimebutine or nor-trimebutine), are also shown to bind to opoid receptors on brain membranes and myenteric synaptosomes. Possible side effects of using trimebutine may include dry mouth, heartburn, nausea, and drowsiness.