Tachyphylaxis

Tachyphylaxis (Greek ταχύς, tachys, "rapid", and φύλαξις, phylaxis, "protection") is a medical term describing an acute, sudden decrease in response to a drug after its administration;[1] i.e. a rapid and short-term onset of drug tolerance. It can occur after an initial dose or after a series of small doses. Increasing the dose of the drug may be able to restore the original response.[2]

Characteristics[edit]

Tachyphylaxis is characterized by the rate sensitivity: the response of the system depends on the rate with which a stimulus is presented. To be specific, a high-intensity prolonged stimulus or often-repeated stimulus may bring about a diminished response also known as desensitization.

Molecular interaction[edit]

In biological sciences, molecular interactions are the physical bases of the operation of the system. The control of the operation, in general, involves interaction of a stimulus molecule with a receptor/enzyme subsystem by, typically, binding to the macromolecule A and causing an activation or an inhibition of the subsystem by forming an activated form of the macromolecule B. The following schematic represents the activity:

where p is the activation rate coefficient. It is customary that p is called a rate constant, but, since the p stands for measure of the intensity of the stimulus causing the activation, p may be variable (non-constant).

More complete is an open system, namely, in its simplest form,

where R stands for the rate of production of A, p(S) is the activation rate coefficient explicitly expressing its dependence on the stimulus intensity S and q represents the rate coefficient of removal from the state B. In this elementally open system the steady state of B always equal to R/q.

The above scheme is only the necessary condition for the rate sensitivity phenomenon, and other pathways of deactivation of B may be considered, with the subsequent return to the inactive form of the receptor/enzyme A. Examples[3][4][5] offer particular use of such (mathematical) models in endocrinology, physiology and pharmacology.

Examples[edit]

Psychedelics[edit]

Psychedelics such as LSD,[6] and psilocybin-containing mushrooms demonstrate very rapid tachyphylaxis.

Opioids[edit]

In a patient fully withdrawn from opioids, going back to an intermittent schedule or maintenance dosing protocol, a fraction of the old tolerance level will rapidly develop, usually starting two days after therapy is resumed and, in general, leveling off after day 7. Whether this is caused directly by opioid receptors modified in the past or affecting a change in some metabolic set-point is unclear. Increasing the dose will usually restore efficacy; relatively rapid opioid rotation may also be of use if the increase in tolerance continues.

Beta-2 agonists[edit]

Inhalation of an agonist for the beta-2 adrenergic receptor, such as salbutamol (albuterol in the US), is the most common treatment for asthma. Polymorphisms of the beta-2 receptor play a role in tachyphylaxis. Expression of the Gly-16 allele (glycine at position 16) results in greater receptor downregulation by endogenous catecholamines at baseline compared to Arg-16. This results in a greater single-use bronchodilator response in individuals homozygous for Arg-16 compared to Gly-16 homozygotes.[7] However, with regular beta-2 agonist use, asthmatic Arg-16 individuals experience a significant decline in bronchodilator response. This decline does not occur in Gly-16 individuals. It has been proposed that the tachyphylactic effect of regular exposure to exogenous beta-2 agonists is more apparent in Arg-16 individuals because their receptors have not been downregulated prior to agonist administration.[8]

Nicotine[edit]

Nicotine may also show tachyphylaxis over the course of a day, although the mechanism of this action is unclear.[9]

Other examples[edit]

Intervention and reversal[edit]

Intranasal decongestants[edit]

Use of intranasal decongestants (such as oxymetazoline) for more than three days leads to tachyphylaxis of response and rebound congestion, caused by alpha-adrenoceptor downregulation and desensitization. The mechanism may specifically include receptor internalisation and resistance to endogenous vasoconstrictors causing worsening in symptoms post use of medication. Oxymetazoline-induced tachyphylaxis and rebound congestion are reversed by intranasal fluticasone. [14]

See also[edit]

References[edit]

  1. ^ Bunnel, Craig A. Intensive Review of Internal Medicine, Harvard Medical School 2009.[page needed]
  2. ^ Lehne, Richard A. (2013). "Tachyphylaxis". Pharmacology for Nursing Care. Philadelphia: Saunders. p. 81. ISBN 978-1-4377-3582-6.
  3. ^ Ekblad EB, Ličko V (January 1984). "A model eliciting transient responses". The American Journal of Physiology. 246 (1 Pt 2): R114–21. doi:10.1152/ajpregu.1984.246.1.R114. PMID 6320668.
  4. ^ Ličko V, Raff H (February 1985). "Rate sensitivity of blood pressure to hypoxia". Journal of Theoretical Biology. 112 (4): 839–845. Bibcode:1985JThBi.112..839L. doi:10.1016/S0022-5193(85)80065-5. PMID 3999765.
  5. ^ Ličko V (1985). "Drugs, Receptors and Tolerance". Pharmacokinetics and Pharmacodynamics of Psychoactive Drugs. pp. 311–322. ISBN 0-931890-20-9.
  6. ^ Buchborn T, Grecksch G, Dieterich D, Hollt V (2016). "Chapter 79 - Tolerance to Lysergic Acid Diethylamide: Overview, Correlates, and Clinical Implications". Neuropathology of Drug Addictions and Substance Misuse. Vol. 2. Academic Press. pp. 848–849. doi:10.1016/B978-0-12-800212-4.00079-0. ISBN 978-0-12-800212-4.
  7. ^ Martinez FD, Graves PE, Baldini M, Solomon S, Erickson R (December 1997). "Association between genetic polymorphisms of the beta2-adrenoceptor and response to albuterol in children with and without a history of wheezing". The Journal of Clinical Investigation. 100 (12): 3184–8. doi:10.1172/JCI119874. PMC 508532. PMID 9399966.
  8. ^ Israel E, Drazen JM, Liggett SB, et al. (July 2000). "The effect of polymorphisms of the beta(2)-adrenergic receptor on the response to regular use of albuterol in asthma" (PDF). American Journal of Respiratory and Critical Care Medicine. 162 (1): 75–80. doi:10.1164/ajrccm.162.1.9907092. PMID 10903223. S2CID 9399149.
  9. ^ Zuo Y, Lu H, Vaupel DB, et al. (November 2011). "Acute nicotine-induced tachyphylaxis is differentially manifest in the limbic system". Neuropsychopharmacology. 36 (12): 2498–512. doi:10.1038/npp.2011.139. PMC 3194077. PMID 21796109.
  10. ^ Mutschler, Ernst; Schäfer-Korting, Monika (2001). Arzneimittelwirkungen (in German) (8 ed.). Stuttgart: Wissenschaftliche Verlagsgesellschaft. pp. 554–558. ISBN 978-3-8047-1763-3.
  11. ^ Benjamin, Ivor (2016-01-01). Andreoli and Carpenter's Cecil Essentials of Medicine. Elsevier Health Sciences. p. 558. ISBN 9781437718997.
  12. ^ "UpToDate". UpToDate. Retrieved 7 Aug 2023.
  13. ^ "nal.usda.gov". Archived from the original on 2008-08-07.
  14. ^ Vaidyanathan S, Williamson P, Clearie K, Khan F, Lipworth B (July 2010). "Fluticasone reverses oxymetazoline-induced tachyphylaxis of response and rebound congestion". American Journal of Respiratory and Critical Care Medicine. 182 (1): 19–24. doi:10.1164/rccm.200911-1701OC. PMID 20203244.

External links[edit]


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