Effects of High-altitude Hypoxia on Drug Metabolism and Pharmacokinetics of Sedative-hypnotic Drugs and Regulatory Mechanism

Lu      Tian; Guiqin      Liu; Junjun      Han; Xiangyang      Li
doi:10.2174/0113892002318723240802100729
Note! Please note that this article is currently in the "Article in Press" stage and is not the final "Version of record". While it has been accepted, copy-edited, and formatted, however, it is still undergoing proofreading and corrections by the authors. Therefore, the text may still change before the final publication. Although "Articles in Press" may not have all bibliographic details available, the DOI and the year of online publication can still be used to cite them. The article title, DOI, publication year, and author(s) should all be included in the citation format. Once the final "Version of record" becomes available the "Article in Press" will be replaced by that.
Abstract

Sedative hypnotics effectively improve sleep quality under high-altitude hypoxia by reducing central nervous system excitability. High-altitude hypoxia causes sleep disorders and modifies the metabolism and mechanisms of drug action, impacting medication therapy's effectiveness. This review aims to provide a theoretical basis for the treatment of central nervous system diseases in high-altitude areas by summarizing the progress and mechanism of sedative-hypnotics in hypoxic environments, as well as the impact of highaltitude hypoxia on sleep.
[1]
Robbins, R.; Quan, S.F.; Buysse, D.J.; Weaver, M.D.; Walker, M.P.; Drake, C.L.; Monten, K.; Barger, L.K.; Rajaratnam, S.M.W.; Roth, T.; Czeisler, C.A. A nationally representative survey assessing restorative sleep in US adults. Frontiers in Sleep,  2022, 1, 935228.
 [http://dx.doi.org/10.3389/frsle.2022.935228] [PMID: 36042946]

[2]
K Pavlova, M.; Latreille, V. Sleep Disorders. Am. J. Med.,  2019, 132(3), 292-299.
 [http://dx.doi.org/10.1016/j.amjmed.2018.09.021] [PMID: 30292731]

[3]
Varghese, N.E.; Lugo, A.; Ghislandi, S.; Colombo, P.; Pacifici, R.; Gallus, S. Sleep dissatisfaction and insufficient sleep duration in the Italian population. Sci. Rep.,  2020, 10(1), 17943.
 [http://dx.doi.org/10.1038/s41598-020-72612-4] [PMID: 33087728]

[4]
Zhou, X.; Nian, Y.; Qiao, Y.; Yang, M.; Xin, Y.; Li, X. Hypoxia plays a key role in the pharmacokinetic changes of drugs at high altitude. Curr. Drug Metab.,  2018, 19(11), 960-969.
 [http://dx.doi.org/10.2174/1389200219666180529112913] [PMID: 29807512]

[5]
Fisher, J.M.; Wrighton, S.A.; Watkins, P.B.; Schmiedlin-Ren, P.; Calamia, J.C.; Shen, D.D.; Kunze, K.L.; Thummel, K.E. First-pass midazolam metabolism catalyzed by 1alpha,25-dihydroxy vitamin D3-modified Caco-2 cell monolayers. J. Pharmacol. Exp. Ther.,  1999, 289(2), 1134-1142.
 [PMID: 10215697]

[6]
Denlinger, C.S.; Ligibel, J.A.; Are, M.; Baker, K.S.; Demark-Wahnefried, W.; Friedman, D.L.; Goldman, M.; Jones, L.; King, A.; Ku, G.H.; Kvale, E.; Langbaum, T.S.; Leonardi-Warren, K.; McCabe, M.S.; Melisko, M.; Montoya, J.G.; Mooney, K.; Morgan, M.A.; Moslehi, J.J.; O’Connor, T.; Overholser, L.; Paskett, E.D.; Raza, M.; Syrjala, K.L.; Urba, S.G.; Wakabayashi, M.T.; Zee, P.; McMillian, N.; Freedman-Cass, D. Survivorship: Sleep disorders, version 1.2014. J. Natl. Compr. Canc. Netw.,  2014, 12(5), 630-642.
 [http://dx.doi.org/10.6004/jnccn.2014.0067] [PMID: 24812132]

[7]
Garrido, E.; Botella de Maglia, J.; Castillo, O. Acute, subacute and chronic mountain sickness. Rev. Clin. Esp. (Barc.),  2021, 221(8), 481-490.
 [http://dx.doi.org/10.1016/j.rceng.2019.12.009] [PMID: 34583826]

[8]
Pena, E.; El Alam, S.; Siques, P.; Brito, J. Oxidative stress and diseases associated with high-altitude exposure. Antioxidants,  2022, 11(2), 267.
 [http://dx.doi.org/10.3390/antiox11020267] [PMID: 35204150]

[9]
Nathansen, A.B.; Møller, A.M. Prophylaxis and treatment of mountain sickness. Ugeskr. Laeger,  2023, 185(13), 06220421.
 [PMID: 36999289]

[10]
Tseng, C.H.; Lin, F.C.; Chao, H.S.; Tsai, H.C.; Shiao, G.M.; Chang, S.C. Impact of rapid ascent to high altitude on sleep. Sleep Breath.,  2015, 19(3), 819-26.
 [http://dx.doi.org/10.1007/s11325-014-1093-7.]

[11]
Nussbaumer-Ochsner, Y.; Schuepfer, N.; Ursprung, J.; Siebenmann, C.; Maggiorini, M.; Bloch, K.E. Sleep and breathing in high altitude pulmonary edema susceptible subjects at 4,559 meters. Sleep,  2012, 35(10), 1413-1421.
 [http://dx.doi.org/10.5665/sleep.2126] [PMID: 23024440]

[12]
Furian, M.; Bitos, K.; Hartmann, S.E.; Muralt, L.; Lichtblau, M.; Bader, P.R.; Rawling, J.M.; Ulrich, S.; Poulin, M.J.; Bloch, K.E. Acute high altitude exposure, acclimatization and re-exposure on nocturnal breathing. Front. Physiol.,  2022, 13, 965021.
 [http://dx.doi.org/10.3389/fphys.2022.965021] [PMID: 36134332]

[13]
Lancaster, G.; Debevec, T.; Millet, G.P.; Poussel, M.; Willis, S.J.; Mramor, M.; Goričar, K.; Osredkar, D.; Dolžan, V.; Stefanovska, A. Relationship between cardiorespiratory phase coherence during hypoxia and genetic polymorphism in humans. J. Physiol.,  2020, 598(10), 2001-2019.
 [http://dx.doi.org/10.1113/JP278829] [PMID: 31957891]

[14]
Anholm, J.D.; Powles, A.C.P.; Downey, R., III; Houston, C.S.; Sutton, J.R.; Bonnet, M.H.; Cymerman, A. Operation Everest II: Arterial oxygen saturation and sleep at extreme simulated altitude. Am. Rev. Respir. Dis.,  1992, 145(4_pt_1), 817-826.
 [http://dx.doi.org/10.1164/ajrccm/145.4_Pt_1.817] [PMID: 1554208]

[15]
Pramsohler, S.; Schilz, R.; Patzak, A.; Rausch, L.; Netzer, N.C. Periodic breathing in healthy young adults in normobaric hypoxia equivalent to 3500 m, 4500 m, and 5500 m altitude. Sleep Breath.,  2019, 23(2), 703-709.
 [http://dx.doi.org/10.1007/s11325-019-01829-z] [PMID: 30972693]

[16]
Kryger, M.; Glas, R.; Jackson, D.; McCullough, R.E.; Scoggin, C.; Grover, R.F.; Weil, J.V. Impaired oxygenation during sleep in excessive polycythemia of high altitude: Improvement with respiratory stimulation. Sleep,  1978, 1(1), 3-17.
 [http://dx.doi.org/10.1093/sleep/1.1.3] [PMID: 756057]

[17]
Ju, J.D.; Zhang, C.; Sgambati, F.P.; Lopez, L.M.; Pham, L.V.; Schwartz, A.R.; Accinelli, R.A. Acute altitude acclimatization in young healthy volunteers: Nocturnal oxygenation increases over time, whereas periodic breathing persists. High Alt. Med. Biol.,  2021, 22(1), 14-23.
 [http://dx.doi.org/10.1089/ham.2020.0009] [PMID: 33185483]

[18]
Bird, J.D.; Kalker, A.; Rimke, A.N.; Chan, J.S.; Chan, G.; Saran, G.; Jendzjowsky, N.G.; Wilson, R. J.A.; Brutsaert, T.D.; Sherpa, M.T.; Day, T.A. Severity of central sleep apnea does not affect sleeping oxygen saturation during ascent to high altitude. J Appl Physiol (1985).,  2021, 131(5), 1432-1443.
 [http://dx.doi.org/10.1152/japplphysiol.00363.2021.]

[19]
Beaumont, M.; Batéjat, D.; Coste, O.; van Beers, P.; Colas, A.; Clère, J.M.; Piérard, C. Effects of zolpidem and zaleplon on sleep, respiratory patterns and performance at a simulated altitude of 4,000 m. Neuropsychobiology,  2004, 49(3), 154-162.
 [http://dx.doi.org/10.1159/000076723] [PMID: 15034230]

[20]
Tanner, J.B.; Tanner, S.M.E.; Thapa, G.B.; Chang, Y.; Watson, K.L.M.; Staunton, E.; Howarth, C.; Basnyat, B.; Harris, N.S. A randomized trial of temazepam versus acetazolamide in high altitude sleep disturbance. High Alt. Med. Biol.,  2013, 14(3), 234-239.
 [http://dx.doi.org/10.1089/ham.2013.1023] [PMID: 24028643]

[21]
Erman, M.K. Influence of pharmacokinetic profiles on safety and efficacy of hypnotic medications.  J Clin Psychiatry,  2006, 67, 9-12. Available from: https://hero.epa.gov/hero/index.cfm/reference/details/reference_id/469008

[22]
Wang, Q.; Jiang, T.; Li, C. Overview of recent literature on diazepam adverse reactions. Chinese Journal of Drug Abuse Prevention and Control.,  2014, 20(04), 233-234.

[23]
Liu, F.; Lu, Z. Interpretation of the key points of the expert consensus on the clinical use of benzodiazepines. World Clinical.,  2018, 39(10), 716-720.

[24]
Li, W.; Wang, L.; Fan, Z. Catabolic kinetics of diazepam and its I and II phase metabolites in human urine. Chinese forensic impurities.,  2023, 38(3), 273-276.

[25]
Hofmann, J.I.; Schwarz, C.; Rudolph, U.; Antkowiak, B. Effects of diazepam on low-frequency and high-frequency electrocortical γ-power mediated by α1- and α2-GABAA receptors. Int. J. Mol. Sci.,  2019, 20(14), 3486.
 [http://dx.doi.org/10.3390/ijms20143486] [PMID: 31315211]

[26]
Howland, R.H. Safety and abuse liability of Oxazepam: Is this benzodiazepine drug underutilized? J. Psychosoc. Nurs. Ment. Health Serv.,  2016, 54(4), 22-25.
 [http://dx.doi.org/10.3928/02793695-20160322-01] [PMID: 27042924]

[27]
Luo, T.; Hao, W. Research progress of oxazepam. Int. J. Psychiatry,  2010, 37(4), 244-247.

[28]
Denisov, I.G.; Grinkova, Y.V.; Camp, T.; McLean, M.A.; Sligar, S.G. Midazolam as a probe for drug–drug interactions mediated by CYP3A4: Homotropic allosteric mechanism of site-specific hydroxylation. Biochemistry,  2021, 60(21), 1670-1681.
 [http://dx.doi.org/10.1021/acs.biochem.1c00161] [PMID: 34015213]

[29]
Venkatapura Chandrashekar, D.; DuBois, B.; Mehvar, R. UPLC-MS/MS analysis of the Michaelis-Menten kinetics of CYP3A-mediated midazolam 1′- and 4-hydroxylation in rat brain microsomes. J. Chromatogr. B Analyt. Technol. Biomed. Life Sci.,  2021, 1180, 122892.
 [http://dx.doi.org/10.1016/j.jchromb.2021.122892] [PMID: 34388602]

[30]
Salman, S.; Tang, E.K.Y.; Cheung, L.C.; Nguyen, M.N.; Sommerfield, D.; Slevin, L.; Lim, L.Y.; von Ungern Sternberg, B.S. A novel, palatable paediatric oral formulation of midazolam: Pharmacokinetics, tolerability, efficacy and safety. Anaesthesia,  2018, 73(12), 1469-1477.
 [http://dx.doi.org/10.1111/anae.14318] [PMID: 29984832]

[31]
Hollister, L.E. Principles of therapeutic applications of benzodiazepines. J. Psychoactive Drugs,  1983, 15(1-2), 41-44.
 [http://dx.doi.org/10.1080/02791072.1983.10472120] [PMID: 6136568]

[32]
Włodarczyk, A.; Szarmach, J.; Cubała, W.J.; Wiglusz, M.S. Benzodiazepines in combination with antipsychotic drugs for schizophrenia: GABA-ergic targeted therapy. Psychiatr. Danub.,  2017, 29(3), 345-348.
 [PMID: 28953788]

[33]
Zhu, J.; Yang, J.; Nian, Y.; Liu, G.; Duan, Y.; Bai, X.; Wang, Q.; Zhou, Y.; Wang, X.; Qu, N.; Li, X. Pharmacokinetics of acetaminophen and metformin hydrochloride in rats after exposure to simulated high altitude hypoxia. Front. Pharmacol.,  2021, 12, 692349.
 [http://dx.doi.org/10.3389/fphar.2021.692349] [PMID: 34220516]

[34]
Gong, W.; Liu, S.; Xu, P.; Fan, M.; Xue, M. Simultaneous quantification of diazepam and dexamethasone in plasma by high-performance liquid chromatography with tandem mass spectrometry and its application to a pharmacokinetic comparison between normoxic and hypoxic rats. Molecules,  2015, 20(4), 6901-6912.
 [http://dx.doi.org/10.3390/molecules20046901] [PMID: 25913929]

[35]
Vij, A.G.; Kishore, K.; Dey, J. Effect of intermittent hypobaric hypoxia on efficacy & clearance of drugs. Indian J. Med. Res.,  2012, 135(2), 211-216.
 [PMID: 22446863]

[36]
Wilbraham, D.; Berg, P.H.; Tsai, M.; Liffick, E.; Loo, L.S.; Doty, E.G.; Sellers, E. Abuse potential of Lasmiditan: A phase 1 randomized, placebo- and alprazolam-controlled crossover study. J. Clin. Pharmacol.,  2020, 60(4), 495-504.
 [http://dx.doi.org/10.1002/jcph.1543] [PMID: 31745991]

[37]
Bland, H.; Li, X.; Mangin, E.; Yee, K.L.; Lines, C.; Herring, W.J.; Gillespie, G. Effects of bedtime dosing with suvorexant and zolpidem on balance and psychomotor performance in healthy elderly participants during the night and in the morning. J. Clin. Psychopharmacol.,  2021, 41(4), 414-420.
 [http://dx.doi.org/10.1097/JCP.0000000000001439] [PMID: 34181362]

[38]
Pasupuleti, B.; Gone, V.; Baddam, R.; Venisetty, R.K.; Prasad, O.P. Clinical impact of co-medication of levetiracetam and clobazam with proton pump inhibitors: A drug interaction study. Curr. Drug Metab.,  2020, 21(2), 126-131.
 [http://dx.doi.org/10.2174/1389200221666200218121050] [PMID: 32067615]

[39]
Hirota, N.; Ito, K.; Iwatsubo, T.; Green, C.E.; Tyson, C.A.; Shimada, N.; Suzuki, H.; Sugiyama, Y. In Vitro / in vivo scaling of alprazolam metabolism by CYP3A4 and CYP3A5 in humans. Biopharm. Drug Dispos.,  2001, 22(2), 53-71.
 [http://dx.doi.org/10.1002/bdd.261] [PMID: 11745908]

[40]
Wu, Q.; Hu, Y.; Wang, C.; Wei, W.; Gui, L.; Zeng, W.; Liu, C.; Jia, W.; Miao, J.; Lan, K. Reevaluate in vitro CYP3A Index reactions of benzodiazepines and steroids between humans and dogs. Drug Metab. Dispos.,  2022, 50(6), 741-749.
 [http://dx.doi.org/10.1124/dmd.122.000864] [PMID: 35351776]

[41]
Senda, C.; Kishimoto, W.; Sakai, K.; Nagakura, A.; Igarashi, T. Identification of human cytochrome P450 isoforms involved in the metabolism of brotizolam. Xenobiotica,  1997, 27(9), 913-922.
 [http://dx.doi.org/10.1080/004982597240082] [PMID: 9381732]

[42]
Ujiie, Y.; Fukasawa, T.; Yasui-Furukori, N.; Suzuki, A.; Tateishi, T.; Otani, K. Rifampicin markedly decreases plasma concentration and hypnotic effect of brotizolam. Ther. Drug Monit.,  2006, 28(3), 299-302.
 [http://dx.doi.org/10.1097/01.ftd.0000200010.33430.0e] [PMID: 16778710]

[43]
Giraud, C.; Tran, A.; Rey, E.; Vincent, J.; Tréluyer, J.M.; Pons, G. In vitro characterization of clobazam metabolism by recombinant cytochrome P450 enzymes: Importance of CYP2C19. Drug Metab. Dispos.,  2004, 32(11), 1279-1286.
 [http://dx.doi.org/10.1124/dmd.32.11.1279] [PMID: 15483195]

[44]
Tolbert, D.; Larsen, F. A comprehensive overview of the clinical pharmacokinetics of clobazam. J. Clin. Pharmacol.,  2019, 59(1), 7-19.
 [http://dx.doi.org/10.1002/jcph.1313] [PMID: 30285275]

[45]
Greenblatt, D.J.; Harmatz, J.S.; Zhang, Q.; Chen, Y.; Shader, R.I. Slow accumulation and elimination of diazepam and its active metabolite with extended treatment in the elderly. J. Clin. Pharmacol.,  2021, 61(2), 193-203.
 [http://dx.doi.org/10.1002/jcph.1726] [PMID: 32856316]

[46]
Zubiaur, P.; Figueiredo-Tor, L.; Villapalos-García, G.; Soria-Chacartegui, P.; Navares-Gómez, M.; Novalbos, J.; Matas, M.; Calleja, S.; Mejía-Abril, G.; Román, M.; Ochoa, D.; Abad-Santos, F. Association between CYP2C19 and CYP2B6 phenotypes and the pharmacokinetics and safety of diazepam. Biomed. Pharmacother.,  2022, 155, 113747.
 [http://dx.doi.org/10.1016/j.biopha.2022.113747] [PMID: 36162369]

[47]
Al Bahri, A.A.; Hamnett, H.J. Etizolam and its major metabolites: A short review. J. Anal. Toxicol.,  2023, 47(3), 216-226.
 [http://dx.doi.org/10.1093/jat/bkac096] [PMID: 36477341]

[48]
Jie, Z.; Qin, S.; Liu, F.; Xu, D.; Sun, J.; Qin, G.; Hou, X.; Xu, P.; Zhang, W.; Gao, C.; Lu, J. Analysis on dynamic changes of etizolam and its metabolites and exploration of its development prospect using UPLC-Q-exactive-MS. J. Pharm. Biomed. Anal.,  2024, 240, 115936.
 [http://dx.doi.org/10.1016/j.jpba.2023.115936] [PMID: 38183733]

[49]
Kilicarslan, T.; Haining, R.L.; Rettie, A.E.; Busto, U.; Tyndale, R.F.; Sellers, E.M. Flunitrazepam metabolism by cytochrome P450S 2C19 and 3A4. Drug Metab. Dispos.,  2001, 29(4 Pt 1), 460-465.
 [PMID: 11259331]

[50]
Katselou, M.; Papoutsis, I.; Nikolaou, P.; Spiliopoulou, C.; Athanaselis, S. Metabolites replace the parent drug in the drug arena. The cases of fonazepam and nifoxipam. Forensic Toxicol.,  2017, 35(1), 1-10.
 [http://dx.doi.org/10.1007/s11419-016-0338-5] [PMID: 28127407]

[51]
van Groen, B.D.; Krekels, E.H.J.; Mooij, M.G.; van Duijn, E.; Vaes, W.H.J.; Windhorst, A.D.; van Rosmalen, J.; Hartman, S.J.F.; Hendrikse, N.H.; Koch, B.C.P.; Allegaert, K.; Tibboel, D.; Knibbe, C.A.J.; de Wildt, S.N. The oral bioavailability and metabolism of midazolam in stable critically Ill children: A pharmacokinetic microtracing study. Clin. Pharmacol. Ther.,  2021, 109(1), 140-149.
 [http://dx.doi.org/10.1002/cpt.1890] [PMID: 32403162]

[52]
Jeong, W.; Sunwoo, J.; You, Y.; Park, J.S.; Min, J.H.; In, Y.N.; Ahn, H.J.; Jeon, S.Y.; Hong, J.H.; Song, J.H.; Kang, H.; Nguyen, M.T.T.; Kim, J.; Kang, C. Distribution and elimination kinetics of midazolam and metabolites after post-resuscitation care: A prospective observational study. Sci. Rep.,  2024, 14(1), 4574.
 [http://dx.doi.org/10.1038/s41598-024-54968-z] [PMID: 38403792]

[53]
Miura, M.; Ohkubo, T. In vitro metabolism of quazepam in human liver and intestine and assessment of drug interactions. Xenobiotica,  2004, 34(11-12), 1001-1011.
 [http://dx.doi.org/10.1080/02772240400015214] [PMID: 15801544]

[54]
Zhou, J.; Yamaguchi, K.; Ohno, Y. Quantitative analysis of quazepam and its metabolites in human blood, urine, and bile by liquid chromatography–tandem mass spectrometry. Forensic Sci. Int.,  2014, 241, e5-e12.
 [http://dx.doi.org/10.1016/j.forsciint.2014.04.027] [PMID: 24856286]

[55]
Li, X.; Wang, X.; Li, Y.; Zhu, J.; Su, X.; Yao, X.; Fan, X.; Duan, Y. The activity, protein, and mRNA expression of CYP2E1 and CYP3A1 in rats after exposure to acute and chronic high altitude hypoxia. High Alt. Med. Biol.,  2014, 15(4), 491-496.
 [http://dx.doi.org/10.1089/ham.2014.1026] [PMID: 25330250]

[56]
Li, X.; Wang, X.; Li, Y.; Yuan, M.; Zhu, J.; Su, X.; Yao, X.; Fan, X.; Duan, Y. Effect of exposure to acute and chronic high-altitude hypoxia on the activity and expression of CYP1A2, CYP2D6, CYP2C9, CYP2C19 and NAT2 in rats. Pharmacology,  2014, 93(1-2), 76-83.
 [http://dx.doi.org/10.1159/000358128] [PMID: 24557547]

[57]
Li, W.; Li, J.; Wang, R.; Xie, H.; Jia, Z. MDR1 will play a key role in pharmacokinetic changes under hypoxia at high altitude and its potential regulatory networks. Drug Metab. Rev.,  2015, 47(2), 191-198.
 [http://dx.doi.org/10.3109/03602532.2015.1007012] [PMID: 25639892]

[58]
Ribeiro, A.L.; Ribeiro, V. Drug metabolism and transport under hypoxia. Curr. Drug Metab.,  2013, 14(9), 969-975.
 [http://dx.doi.org/10.2174/1389200211314090003] [PMID: 24160293]

[59]
Zhang, J.; Zhang, M.; Zhang, J.; Wang, R. Enhanced P-glycoprotein expression under high-altitude hypoxia contributes to increased phenytoin levels and reduced clearance in rats. Eur. J. Pharm. Sci.,  2020, 153, 105490.
 [http://dx.doi.org/10.1016/j.ejps.2020.105490] [PMID: 32721527]

[60]
Taskshita, Y.; Ransohoff, R.M. Blood-brain barrier and neurolongical diseasea. Clin. Exp. Immunol.,  2015, 6, 351-261.

[61]
Guo, P.; Zhou, Q.; Luo, H.; Yuan, Y.; Zhou, B. Effects of sodium heptadecyl saponin on changes in blood-cerebrospinal fluid barrier permeability and its anti-leakage mechanism in rats exposed to hypoxia. J. PLA Med. Sci.,  2012, 37(02), 98-103.

[62]
Liu, M.; Alkayed, N.J. Hypoxic preconditioning and tolerance via hypoxia inducible factor (HIF) 1alpha-linked induction of P450 2C11 epoxygenase in astrocytes. J. Cereb. Blood Flow Metab.,  2005, 25(8), 939-948.
 [http://dx.doi.org/10.1038/sj.jcbfm.9600085] [PMID: 15729289]

[63]
Ronaldson, P.T.; Davis, T.P. Regulation of blood–brain barrier integrity by microglia in health and disease: A therapeutic opportunity. J. Cereb. Blood Flow Metab.,  2020, 40(1_suppl), S6-S24.
 [http://dx.doi.org/10.1177/0271678X20951995] [PMID: 32928017]

[64]
Duan, Y.; Zhu, J.; Yang, J.; Liu, G.; Bai, X.; Qu, N.; Wang, X.; Li, X. Regulation of high-altitude hypoxia on the transcription of CYP450 and UGT1A1 mediated by PXR and CAR. Front. Pharmacol.,  2020, 11, 574176.
 [http://dx.doi.org/10.3389/fphar.2020.574176] [PMID: 33041817]

[65]
Yang, J. Transcriptional regulation of CYP450 by HNF1α and HNF4α under plateau hypoxia. Qinghai University, 2023.

[66]
Payne, C.T.; Tabassum, S.; Wu, S.; Hu, H.; Gusdon, A.M.; Choi, H.A.; Ren, X.S. Role of microRNA-34a in blood–brain barrier permeability and mitochondrial function in ischemic stroke. Front. Cell. Neurosci.,  2023, 17, 1278334.
 [http://dx.doi.org/10.3389/fncel.2023.1278334] [PMID: 37927446]

[67]
Caballero-Garrido, E.; Pena-Philippides, J.C.; Lordkipanidze, T.; Bragin, D.; Yang, Y.; Erhardt, E.B.; Roitbak, T. In vivo inhibition of miR-155 promotes recovery after experimental mouse stroke. J. Neurosci.,  2015, 35(36), 12446-12464.
 [http://dx.doi.org/10.1523/JNEUROSCI.1641-15.2015] [PMID: 26354913]

[68]
Redell, J.B.; Zhao, J.; Dash, P.K. Altered expression of miRNA-21 and its targets in the hippocampus after traumatic brain injury. J. Neurosci. Res.,  2011, 89(2), 212-221.
 [http://dx.doi.org/10.1002/jnr.22539] [PMID: 21162128]

[69]
Duan, Y.; Zhu, J.; Yang, J.; Gu, W.; Bai, X.; Liu, G.; Xiangyang, L. A decade’s review of miRNA: A Center of transcriptional regulation of drugmetabolizing enzymes and transporters under hypoxia. Curr. Drug Metab.,  2021, 22(9), 709-725.
 [http://dx.doi.org/10.2174/1389200222666210514011313] [PMID: 33992050]

[70]
Nakano, M.; Nakajima, M. Pharmacology magazine. Folia pharmacologica Japonica, 2019. Available from: https://jams.med.or.jp/journal_list/005_8e.html

[71]
Yu, A.M.; Tian, Y.; Tu, M.J.; Ho, P.Y.; Jilek, J.L. MicroRNA pharmacoepigenetics: Posttranscriptional regulation mechanisms behind variable drug disposition and strategy to develop more effective therapy. Drug Metab. Dispos.,  2016, 44(3), 308-319.
 [http://dx.doi.org/10.1124/dmd.115.067470] [PMID: 26566807]

[72]
Rieger, J.K.; Reutter, S.; Hofmann, U.; Schwab, M.; Zanger, U.M. Inflammation-associated microRNA-130b down-regulates cytochrome P450 activities and directly targets CYP2C9. Drug Metab. Dispos.,  2015, 43(6), 884-888.
 [http://dx.doi.org/10.1124/dmd.114.062844] [PMID: 25802328]

[73]
Kugler, N.; Klein, K.; Zanger, U.M. MiR-155 and other microRNAs downregulate drug metabolizing cytochromes P450 in inflammation. Biochem. Pharmacol.,  2020, 171, 113725.
 [http://dx.doi.org/10.1016/j.bcp.2019.113725] [PMID: 31758923]

[74]
Xie, Y.; Shao, Y.; Deng, X.; Wang, M.; Chen, Y. MicroRNA-298 reverses multidrug resistance to antiepileptic drugs by suppressing MDR1/P-gp expression in vitro. Front. Neurosci.,  2018, 12, 602.
 [http://dx.doi.org/10.3389/fnins.2018.00602] [PMID: 30210283]

[75]
Jiang, W.; Wu, Y.; Jiang, W. MicroRNA-18a decreases choroidal endothelial cell proliferation and migration by inhibiting HIF1A expression. Med. Sci. Monit.,  2015, 21, 1642-1647.
 [http://dx.doi.org/10.12659/MSM.893068] [PMID: 26044722]

[76]
Umezu, T.; Tadokoro, H.; Azuma, K.; Yoshizawa, S.; Ohyashiki, K.; Ohyashiki, J.H. Exosomal miR-135b shed from hypoxic multiple myeloma cells enhances angiogenesis by targeting factor-inhibiting HIF-1. Blood,  2014, 124(25), 3748-3757.
 [http://dx.doi.org/10.1182/blood-2014-05-576116] [PMID: 25320245]

[77]
Dai, L.; Lou, W.; Zhu, J.; Zhou, X.; Di, W. MiR-199a inhibits the angiogenic potential of endometrial stromal cells under hypoxia by targeting HIF-1α/VEGF pathway. Int. J. Clin. Exp. Pathol.,  2015, 8(5), 4735-4744.
 [PMID: 26191163]

[78]
Ghosh, G.; Subramanian, I.V.; Adhikari, N.; Zhang, X.; Joshi, H.P.; Basi, D.; Chandrashekhar, Y.S.; Hall, J.L.; Roy, S.; Zeng, Y.; Ramakrishnan, S. Hypoxia-induced microRNA-424 expression in human endothelial cells regulates HIF-α isoforms and promotes angiogenesis. J. Clin. Invest.,  2010, 120(11), 4141-4154.
 [http://dx.doi.org/10.1172/JCI42980] [PMID: 20972335]

[79]
Altamura, A.C.; Moliterno, D.; Paletta, S.; Maffini, M.; Mauri, M.C.; Bareggi, S. Understanding the pharmacokinetics of anxiolytic drugs. Expert Opin. Drug Metab. Toxicol.,  2013, 9(4), 423-440.
 [http://dx.doi.org/10.1517/17425255.2013.759209] [PMID: 23330992]

[80]
Griffin, C.E., III; Kaye, A.M.; Bueno, F.R.; Kaye, A.D. Benzodiazepine pharmacology and central nervous system-mediated effects. Ochsner J.,  2013, 13(2), 214-223.
 [PMID: 23789008]

[81]
Nilsson, G.E.; Lutz, P.L. Role of GABA in hypoxia tolerance, metabolic depression and hibernation—Possible links to neurotransmitter evolution. Comp. Biochem. Physiol. C Comp. Pharmacol.,  1993, 105(3), 329-336.
 [http://dx.doi.org/10.1016/0742-8413(93)90069-W] [PMID: 7900957]

[82]
Kaufmann, W.A.; Humpel, C.; Alheid, G.F.; Marksteiner, J. Compartmentation of alpha 1 and alpha 2 GABAA receptor subunits within rat extended amygdala: Implications for benzodiazepine action. Brain Res.,  2003, 964(1), 91-99.
 [http://dx.doi.org/10.1016/S0006-8993(02)04082-9] [PMID: 12573516]

[83]
Abbott, N.J. Prediction of blood–brain barrier permeation in drug discovery from in vivo, in vitro and in silico models. Drug Discov. Today. Technol.,  2004, 1(4), 407-416.
 [http://dx.doi.org/10.1016/j.ddtec.2004.11.014] [PMID: 24981621]

[84]
Alavijeh, M.S.; Chishty, M.; Qaiser, M.Z.; Palmer, A.M. Drug metabolism and pharmacokinetics, the blood-brain barrier, and central nervous system drug discovery. NeuroRx,  2005, 2(4), 554-571.
 [http://dx.doi.org/10.1602/neurorx.2.4.554] [PMID: 16489365]

[85]
Kulkarni, A.D.; Patel, H.M.; Surana, S.J.; Belgamwar, V.S.; Pardeshi, C.V. Brain–blood ratio: Implications in brain drug delivery. Expert Opin. Drug Deliv.,  2016, 13(1), 85-92.
 [http://dx.doi.org/10.1517/17425247.2016.1092519] [PMID: 26393289]
Rights & Permissions Print Cite
Journal Information
For Authors
For Editors
For Reviewers
Explore Articles
Open Access
Open Access Articles
For Visitors
DOI https://dx.doi.org/10.2174/0113892002318723240802100729	Print ISSN 1389-2002
Publisher Name Bentham Science Publisher	Online ISSN 1875-5453
Current Drug Metabolism

Effects of High-altitude Hypoxia on Drug Metabolism and Pharmacokinetics of Sedative-hypnotic Drugs and Regulatory Mechanism

Abstract Play Pause

Related Journals

Related Books

Abstract
