Dihydroartemisinin

Dihydroartemisinin
Systematic (IUPAC) name
(3R,5aS,6R,8aS,9R,12S,12aR)-decahydro-3,6,9-trimethyl-3,12-epoxy-12H-pyrano[4,3-j]-1,2-benzodioxepin-10-ol
Clinical data
AHFS/Drugs.com International Drug Names
Routes of
administration
Oral
Legal status
Legal status
  • ℞ (Prescription only)
Pharmacokinetic data
Bioavailability 12%
Metabolism Liver
Biological half-life About 4-11 hours
Excretion Mainly Bile
Identifiers
CAS Number 71939-50-9 YesY
ATC code P01BE05 (WHO)
PubChem CID 107770
ChemSpider 2272104 YesY
UNII 6A9O50735X YesY
ChEMBL CHEMBL25164 N
Chemical data
Formula C15H24O5
Molar mass 284.35 g/mol
 NYesY (what is this?)  (verify)

Dihydroartemisinin (also known as dihydroqinghaosu, artenimol or DHA) is a drug used to treat malaria. Dihydroartemisinin is the active metabolite of all artemisinin compounds (artemisinin, artesunate, artemether, etc.) and is also available as a drug in itself. It is a semi-synthetic derivative of artemisinin and is widely used as an intermediate in the preparation of other artemisinin-derived antimalarial drugs.[1] It is sold commercially in combination with piperaquine and has been shown to be equivalent to artemether/lumefantrine.[2]

Chemistry

The lactone of artemisinin could selectively be reduced with mild hydride-reducing agents, such as sodium borohydride, potassium borohydride, and lithium borohydride to dihydroartemisinin (a lactol) in over 90% yield. It is a novel reduction, because normally lactone cannot be reduced with sodium borohydride under the same reaction conditions (0-5 ˚C in methanol). Reduction with LiAlH4 leads to some rearranged products. It was surprising to find that the lactone was reduced, but that the peroxy group survived. However, the lactone of deoxyartemisinin resisted reduction with sodium borohydride and could only be reduced with diisobutylaluminium hydride to the lactol deoxydihydroartimisinin. These results show that the peroxy group assists the reduction of lactone with sodium borohydride to a lactol, but not to the alcohol which is the over-reduction product. No clear evidence for this reduction process exists.

Mechanism

Seeds

The proposed mechanism of action of artemisinin involves cleavage of endoperoxide bridges by iron, producing free radicals (hypervalent iron-oxo species, epoxides, aldehydes, and dicarbonyl compounds) which damage biological macromolecules causing oxidative stress in the cells of the parasite.[3] Malaria is caused by apicomplexans, primarily Plasmodium falciparum, which largely reside in red blood cells and itself contains iron-rich heme-groups (in the form of hemozoin).[4] In 2015 artemisinin was shown to bind to a large number targets suggesting that it acts in a promiscuous manner.[5]Recent mechanism research discovered that artemisinin targets a broad spectrum of proteins in human cancer cell proteome through heme-activated radical alkylation. [6]

Dosing

Dihydroartemisinin is available as a fixed drug combination with piperaquine (each tablet contains 40 mg of dihydroartemisinin and 320 mg of piperaquine).

The adult dose is 1.6/12.8 mg/kg per dose (rounded up or down to the nearest half tablet) given at 0 h, 8 h, 24 h, and 48 h. Alternatively, the same total dose may be given once daily for three days.[7]

Antimalarial activity

In a systematic review of randomized controlled trials, both dihydroartemisinin-piperaquine and artemether-lumefantrine are very effective at treating malaria (high quality evidence). However, dihydroartemisinin-piperaquine cures slightly more patients than artemether-lumefantrine, and it also prevents further malaria infections for longer after treatment (high quality evidence). Dihydroartemisinin-piperaquine and artemether-lumefantrine probably have similar side effects (moderate quality evidence). The studies were all conducted in Africa. In studies of people living in Asia, dihydroartemisinin-piperaquine is as effective as artesunate plus mefloquine at treating malaria (moderate quality evidence). Artesunate plus mefloquine probably causes more nausea, vomiting, dizziness, sleeplessness, and palpitations than dihydroartemisinin-piperaquine (moderate quality evidence).[8]

Activity as experimental cancer chemotherapeutic

Accumulative research suggests that dihydroartemisinin and other artemisinin-based endoperoxide compounds may display activity as experimental cancer chemotherapeutics.[9] Recent pharmacological evidence demonstrates that dihydroartemisinin targets human metastatic melanoma cells with induction of NOXA-dependent mitochondrial apoptosis that occurs downstream of iron-dependent generation of cytotoxic oxidative stress.[10]

Commercial preparations

In combination with piperaquine:

Alone (not recommended by WHO due to risk of resistance development):

References

  1. Woo, Soon Hyung; Parker, Michael H.; Ploypradith, Poonsakdi; Northrop, John; Posner, Gary H. (1998). "Direct conversion of pyranose anomeric OH→F→R in the artemisinin family of antimalarial trioxanes". Tetrahedron Letters 39 (12): 1533–6. doi:10.1016/S0040-4039(98)00132-4.
  2. Arinaitwe, Emmanuel; Sandison, Taylor G.; Wanzira, Humphrey; Kakuru, Abel; Homsy, Jaco; Kalamya, Julius; Kamya, Moses R.; Vora, Neil; et al. (2009). "Artemether‐Lumefantrine versus Dihydroartemisinin‐Piperaquine for Falciparum Malaria: A Longitudinal, Randomized Trial in Young Ugandan Children". Clinical Infectious Diseases 49 (11): 1629–37. doi:10.1086/647946. PMID 19877969.
  3. Cumming JN; Ploypradith P; Posner GH (1997). "Antimalarial activity of artemisinin (qinghaosu) and related trioxanes: mechanism(s) of action". Adv. Pharmacol. Advances in Pharmacology 37: 253–97. doi:10.1016/S1054-3589(08)60952-7. ISBN 9780120329380. PMID 8891104.
  4. Gary H. Posner & Paul M. O’Neil (2004). "Knowledge of the Proposed Chemical Mechanism of Action and Cytochrome P450 Metabolism of Antimalarial Trioxanes Like Artemisinin Allows Rational Design of New Antimalarial Peroxides". Acc. Chem. Res. 37 (6): 397–404. doi:10.1021/ar020227u. PMID 15196049.
  5. Zhou Y, Li W, Xiao Y (2016). "Profiling of Multiple Targets of Artemisinin Activated by Hemin in Cancer Cell Proteome". ACS Chemical Biology. doi:10.1021/acschembio.5b01043. PMID 26854499.
  6. Zhou, Yiqing; Li, Weichao; Xiao, Youli (2016-02-10). "Profiling of Multiple Targets of Artemisinin Activated by Hemin in Cancer Cell Proteome". ACS Chemical Biology. doi:10.1021/acschembio.5b01043.
  7. Ashley, E. A.; McGready, R.; Hutagalung, R.; Phaiphun, L.; Slight, T.; Proux, S.; Thwai, K. L.; Barends, M.; et al. (2005). "A Randomized, Controlled Study of a Simple, Once-Daily Regimen of Dihydroartemisinin-Piperaquine for the Treatment of Uncomplicated, Multidrug-Resistant Falciparum Malaria". Clinical Infectious Diseases 41 (4): 425–32. doi:10.1086/432011. PMID 16028147.
  8. Zani, B; Gathu, M; Donegan, S; Olliaro, PL; Sinclair, D (Jan 20, 2014). "Dihydroartemisinin-piperaquine for treating uncomplicated Plasmodium falciparum malaria.". The Cochrane database of systematic reviews 1: CD010927. doi:10.1002/14651858.CD010927. PMID 24443033.
  9. Efferth, Thomas (2006). "Molecular Pharmacology and Pharmacogenomics of Artemisinin and its Derivatives in Cancer Cells". Current Drug Targets 7 (4): 407–21. doi:10.2174/138945006776359412. PMID 16611029.
  10. Cabello, Christopher M.; Lamore, Sarah D.; Bair, Warner B.; Qiao, Shuxi; Azimian, Sara; Lesson, Jessica L.; Wondrak, Georg T. (2011). "The redox antimalarial dihydroartemisinin targets human metastatic melanoma cells but not primary melanocytes with induction of NOXA-dependent apoptosis". Investigational New Drugs 30 (4): 1289–301. doi:10.1007/s10637-011-9676-7. PMC 3203350. PMID 21547369.
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