Biology:Iontophoresis

From HandWiki
Iontophoresis
ICD-9-CM99.27
MedlinePlus007293

Iontophoresis is a process of transdermal drug delivery by use of a voltage gradient on the skin.[1][2] Molecules are transported across the stratum corneum by electrophoresis and electroosmosis and the electric field can also increase the permeability of the skin.[3][4] These phenomena, directly and indirectly, constitute active transport of matter due to an applied electric current. The transport is measured in units of chemical flux, commonly μmol/(cm2*hour). Iontophoresis has experimental, therapeutic and diagnostic applications.

Uses

Laboratory uses

Iontophoresis is useful in laboratory experiments, especially in neuropharmacology.[5] Transmitter molecules naturally pass signals between neurons. By microelectrophoretic techniques, including microiontophoresis, neurotransmitters and other chemical agents can be artificially administered very near living and naturally functioning neurons, the activity of which can be simultaneously recorded. This is used to elucidate their pharmacological properties and natural roles.[6]

Therapeutic uses

Therapeutically, electromotive drug administration (EMDA) delivers a medicine or other chemical through the skin.[7] In a manner of speaking, it is an injection without a needle, and may be described as non-invasive. It is different from dermal patches, which do not rely on an electric field. It drives a charged substance, usually a medication or bioactive agent, transdermally by repulsive electromotive force, through the skin. A small electric current is applied to an iontophoretic chamber placed on the skin, containing a charged active agent and its solvent vehicle. Another chamber or a skin electrode carries the return current. One or two chambers are filled with a solution containing an active ingredient and its solvent vehicle. The positively charged chamber, called the anode, will repel a positively charged chemical species, whereas the negatively charged chamber, called the cathode, will repel a negatively charged species into the skin.[8]

It is used to treat some types of palmar-plantar hyperhidrosis.[9] In the treatment of hyperhidrosis, tap water is often the chosen solution for mild and medium forms. In very serious cases of hyperhidrosis, a solution containing glycopyrronium bromide or glycopyrrolate, a cholinergic inhibitor, can be used.[10][11]

Diagnostic uses

Iontophoresis of acetylcholine is used in research as a way to test the health of the endothelium by stimulating endothelium-dependent generation of nitric oxide and subsequent microvascular vasodilation. Acetylcholine is positively charged and is therefore placed in the anode chamber.

Pilocarpine iontophoresis is often used to stimulate sweat secretion, as part of cystic fibrosis diagnosis.[12]

Reverse iontophoresis is a technique by which molecules are removed from within the body for detection. The negative charge of the skin at buffered pH causes it to be permselective to cations such as sodium and potassium ions, allowing iontophoresis which causes electroosmosis, solvent flow towards the anode. Electroosmosis then causes electrophoresis, by which neutral molecules, including glucose, are transported across the skin. This is currently being used in such devices as the GlucoWatch, which allows for blood glucose detection across skin layers.

See also

References

  1. Guy, Richard H.; Kalia, Yogeshvar N.; Delgado-Charro, M.Begoña; Merino, Virginia; López, Alicia; Marro, Diego (2000). "Iontophoresis: electrorepulsion and electroosmosis". Journal of Controlled Release 64 (1–3): 129–132. doi:10.1016/S0168-3659(99)00132-7. ISSN 0168-3659. PMID 10640651. 
  2. Reinauer, S.; Neusser, A.; Schauf, G.; Holzle, E. (1993). "Iontophoresis with alternating current and direct current offset (AC/DC iontophoresis): a new approach for the treatment of hyperhidrosis". British Journal of Dermatology 129 (2): 166–169. doi:10.1111/j.1365-2133.1993.tb03521.x. ISSN 0007-0963. PMID 7654577. 
  3. Prausnitz, Mark R; Langer, Robert (2008). "Transdermal drug delivery". Nature Biotechnology 26 (11): 1261–1268. doi:10.1038/nbt.1504. ISSN 1087-0156. PMID 18997767. 
  4. Pikal, Michael J. (2001). "The role of electroosmotic flow in transdermal iontophoresis". Advanced Drug Delivery Reviews 46 (1–3): 281–305. doi:10.1016/S0169-409X(00)00138-1. ISSN 0169-409X. PMID 11259844. 
  5. Bryne, John. "Iontophoresis of ACh". University of Texas Medical Center. http://neuroscience.uth.tmc.edu/s1/chapter04.html#ionic_mech. 
  6. Curtis, D.R, (1964). Microelectrophoresis, in Physical Techniques in Biological Research, vol. V, ed. W.L. Nastuk, Academic Press, New York, pp. 144–190.
  7. Dhote, V; Bhatnagar, P; Mishra, P. K.; Mahajan, S. C.; Mishra, D. K. (2012). "Iontophoresis: A Potential Emergence of a Transdermal Drug Delivery System". Scientia Pharmaceutica 80 (1): 1–28. doi:10.3797/scipharm.1108-20. PMID 22396901. 
  8. "Iontophoresis". Electrotherapy on the Web. Tim Watson. http://www.electrotherapy.org/modality/iontophoresis. 
  9. Caufield, T.G. (2013). Iontophoresis to Treat Hyperhydrosis. Tim Caufield PhD LLC. [page needed]
  10. Walling, Hobart W.; Swick, Brian L. (2011). "Treatment Options for Hyperhidrosis". American Journal of Clinical Dermatology 12 (5): 285–95. doi:10.2165/11587870-000000000-00000. PMID 21714579. 
  11. Solish, Nowell; Bertucci, Vince; Dansereau, Alain; Hong, H. Chih-HO; Lynde, Charles; Lupin, Mark; Smith, Kevin C.; Storwick, Greg (2007). "A Comprehensive Approach to the Recognition, Diagnosis, and Severity-Based Treatment of Focal Hyperhidrosis: Recommendations of the Canadian Hyperhidrosis Advisory Committee". Dermatologic Surgery 33 (8): 908–23. doi:10.1111/j.1524-4725.2007.33192.x. PMID 17661933. 
  12. Sam, Amir H.; James T.H. Teo (2010). Rapid Medicine. Wiley-Blackwell. ISBN 978-1-4051-8323-9. [page needed]

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