January 2010 in “HAL (Le Centre pour la Communication Scientifique Directe)” Magnesium and caspase inhibitors help protect hearing after gunshot noise.
November 2025 in “Biomedicine & Pharmacotherapy” Calcium blockers may help prevent hearing loss by protecting hair cells.
January 2024 in “Biological Research” Tiny particles from stem cells can help protect ear cells from antibiotic damage by helping cells remove damaged parts.
13 citations
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November 2017 in “Neurotoxicity research/Neurotoxicity resarch” Sodium metabisulfite increases sodium channel activity, leading to higher cell excitability and potential damage.
April 2023 in “Research Square (Research Square)” Exosomes protect ear hair cells from damage by controlling cell waste removal, potentially helping treat hearing loss.
January 2026 in “Advanced Science” Increasing XIAP and DDRGK1 can help prevent hearing loss from loud noise.
1 citations
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April 2002 in “PubMed” Anti-epileptic drugs may cause visual and hair side effects due to enzyme inhibition, especially in genetically predisposed individuals.
1 citations
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January 2024 CaBP1 and CaBP2 are necessary for proper hearing and neurotransmission in the ear's inner hair cells.
CaBP1 and CaBP2 are necessary for proper hearing and neurotransmission in the ear's inner hair cells.
April 2026 in “Proceedings of the National Academy of Sciences” Tmem30b is essential for hearing by maintaining hair cell structure in the ear.
5 citations
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November 2022 in “Molecular Neurobiology” Melatonin may protect inner ear cells from damage by reducing cell death and oxidative stress, potentially treating sudden hearing loss.
44 citations
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October 2016 in “Epilepsia” 2-DG reduces seizures by enhancing brain inhibition through specific receptor activation.
November 2025 in “British Journal of Pharmacology” Inositol hexaphosphate helps protect hearing by preserving ear cells in mice.
CaBP1 and CaBP2 are important for maintaining hearing by supporting continuous calcium currents and nerve signaling in the ear.
CaBP1 and CaBP2 are important for continuous hearing by preventing inactivation of calcium currents in ear cells, with CaBP2 also able to restore hearing when reintroduced.
12 citations
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June 2025 in “Gut Microbes” BroadAMP-GPT effectively creates antimicrobial peptides to fight drug-resistant bacteria.
11 citations
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September 2011 in “Biochemical journal” Neurotrophin-4 increases calcium current in specific mouse neurons through the PI3K pathway.
CaBP1 and 2 are important for maintaining the activity of calcium channels necessary for hearing in inner ear cells.
2 citations
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August 2002 in “British Journal of Ophthalmology” Tangent screens help detect visual field defects from vigabatrin.
15 citations
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September 2018 in “Hearing research” Rapamycin reduces age-related hearing cell loss in mice, but acarbose does not.
February 2026 in “European Journal of Pharmacology” Teicoplanin may help treat hair loss by reducing androgen receptors and boosting hair cell growth.
March 2026 in “Critical Care Medicine” Hair restoration can cause severe seizures due to combined drug toxicity.
1 citations
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August 2023 in “Genome research” The spiny mouse regenerates ear tissue asymmetrically, with gene expression differences possibly explaining its unique healing abilities.
13 citations
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September 1989 in “International Journal of Dermatology” Carbamazepine may cause reversible nail detachment.
October 2025 in “PLoS ONE” Age-related hearing loss involves cochlear damage and metabolic changes.
8 citations
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April 2017 in “Journal of The Royal Society Interface” Giant axonal neuropathy changes the structure of keratin in human hair.
Low levels of tenuazonic acid can severely damage vital organs.
February 2026 in “Advanced Healthcare Materials” The microneedles effectively treat infected wounds by killing bacteria, reducing inflammation, and promoting healing.
2 citations
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April 2023 in “Curēus” Valproic acid can cause muscle damage and liver issues, which improve after stopping the drug.
1 citations
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August 2023 in “The journal of pharmacology and experimental therapeutics/The Journal of pharmacology and experimental therapeutics” Kir6.1 mutations in Cantú syndrome increase channel sensitivity and hyperpolarization, while SUR2B mutations do not.