30516-87-1 Usage
Description
Zidovudine, also known as azidothymidine (AZT), is an antiviral agent acting via reverse
transcnptase inhibition. It was first launched in the U.K. and subsequently introduced in
over a dozen countries for the management of severe manifestations of HIV infection. In
patients with AIDS and ARC, zidovudine reduces the risk of opportunistic infections and
prolongs survival time. In symptom-free patients it shows promise in halting further
immunological deterioration.
Chemical Properties
Off White Crystalline Powder
Originator
Detroit Inst. Cancer Res. (USA)
Uses
Different sources of media describe the Uses of 30516-87-1 differently. You can refer to the following data:
1. A potent and selective inhibitor of HIV-1 replication
2. antibacterial
3. Zidovudine is an antiretroviral drug that is clinically active against HIV-1 and is intended
to treat HIV-infected patients. Zidovudine is an analog of thymidine that inhibits replication of the AIDS virus. It also turned into mono-, di-, and triphosphates by the same cellular enzymes that catalyze phosphorylation of thymidine and thymidine nucleosides.
Zidovudine-triphosphate is then included in the terminal fragment of the growing chain of
viral DNA by viral reverse transcriptase, thus causing the viral DNA chain to break apart
in cells infected with the virus.
Zidovudine has been authorized for treating patients with AIDS. It significantly prolongs the life of the patient, although it has a number of toxic effects. Synonyms of this
drug are azidothymidine and retrovir.
Definition
ChEBI: A pyrimidine 2',3'-dideoxyribonucleoside compound having a 3'-azido substituent and thymine as the nucleobase.
Indications
Zidovudine was the first agent to be used to prevent the
transmission of HIV from a pregnant woman to her
child. It was given to the mother at 14 to 34 weeks’ gestation
and to the child for the first 6 weeks of life.
Current combination therapies employ zidovudine with
another NRTI and a protease inhibitor.
Manufacturing Process
Preparation of 2,3'-anhydrothymidine Thymidine (85.4 g; 0.353 mol) was dissolved in 500 mL dry DMF (dimethyl
formamide) and added to N-(2-chloro-1,1,2-trifluoroethyl)diethylamine (100.3
g; 0.529 mol) [prepared according to the method of D. E. Ayer, J. Med. Chem.
6, 608 (1963)]. This solution was heated at 70°C for 30 minutes then poured
into 950 mL ethanol with vigorous stirring. The product precipitated from this
solution and was filtered. The ethanol supernatant was refrigerated then
filtered to yield a total of 47.75 g (0.213 mol; 60.3%) of 2,3'-
anhydrothymidine; melting point 228°-230°C.Preparation for 3'-azido-3'-deoxythymidine2,3'-Anhydrothymidine (25 g; 0.1115 mol) and NaN 3 (29 g; 0.446 mol) was
suspended in a mixture of 250 mL DMF and 38 mL H 2 O. The reaction was
refluxed for 5 hours at which time it was poured into 1 liter of H 2 O. This
aqueous solution was extracted with ethyl acetate (EtOAc) (3x700 ml). The
EtOAc was dried over Na 2 SO 4 , filtered, and then EtOAc was removed in vacuo
to yield a viscous oil. This oil was stirred with 200 mL water resulting in a
solid, 3'-azido-3'-deoxythymidine, 9.15 g (0.0342 mol); 30.7%; melting point
116°-118°C.
Brand name
Retrovir (GlaxoSmithKline).
Therapeutic Function
Antiviral, Antineoplastic
Antimicrobial activity
Zidovudine is active against HIV-1, HIV-2 and HTLV-1.
Acquired resistance
As with stavudine, mutations at position 41, 67 and 70, and
positions 210, 215 and 219 (the ‘thymidine analog mutations’)
of the reverse transcriptase genes are associated with
diminished antiretroviral efficacy.
General Description
Different sources of media describe the General Description of 30516-87-1 differently. You can refer to the following data:
1. Slightly off-white odorless powdery solid.
2. Zidovudine, 3'-azido-3'-deoxythymidine or AZT, is ananalog of thymidine that possesses antiviral activityagainst HIV-1, HIV-2, HTLV-1, and several other retroviruses.This nucleoside was synthesized in 1978 by Linand Prusoff as an intermediate in the preparation ofamino acid analogs of thymidine. A screening program directedtoward the identification of agents potentially effectivefor the treatment of patients with AIDS led to the discoveryof its unique antiviral properties 7 years later.Zidovudine is recommended for the management of adultpatients with symptomatic HIV infection (AIDS or ARC)who have a history of confirmed Pneumocystis carinii pneumoniaor an absolute CD4+(T4 or TH cell) lymphocytecount below 200/mm3 before therapy. The hematologicaltoxicity of the drug precludes its use in asymptomatic patients.Anemia and granulocytopenia are the most commontoxic effects associated with AZT.
3. Zidovudine, or 3u-azido-3udeoxythymidine, formerly known as azidothymidine (AZT; BW A509U), is an analog of the nucleoside thymidine. It is an inhibitor of the human immunodeficiency virus (HIV)-encoded enzyme reverse transcriptase. It was the first antiretroviral compound to be licenced for the treatment of people infected with HIV. The compound was synthesized much earlier, however, by Horwitz and colleagues and subsequently used in anticancer research. Zidovudine was developed by Burroughs Wellcome and is now marketed by GlaxoSmithKline under the trade name of Retrovir. Zidovudine is also available in fixed-dose cominations with other nucleoside analog reverse transcriptase inhibitors as Combivir (zidovudine with lamivudine) and Trizivir (zidovudine with lamivudine and abacavir). Generic forms of the drug have been produced by a number of companies and include AVIRO-Z (Ranbaxy Laboratories Ltd) and Zidovir (Cipla Ltd). There are also a number of generic fixed-dose products including zidovudine with lamivudine (e.g. Duovir; Cipla Ltd). Zidovudine is indicated for the treatment and prevention of HIV infection, generally given in combination with other antiretroviral agents.
Air & Water Reactions
Dust may form an explosive mixture in air. Water soluble. Hydrolysis occurs in strongly basic solutions .
Reactivity Profile
Zidovudine is a azido compound. Azo, diazo, azido compounds can detonate. This applies in particular to organic azides that have been sensitized by the addition of metal salts or strong acids. Toxic gases are formed by mixing materials of this class with acids, aldehydes, amides, carbamates, cyanides, inorganic fluorides, halogenated organics, isocyanates, ketones, metals, nitrides, peroxides, phenols, epoxides, acyl halides, and strong oxidizing or reducing agents. Flammable gases are formed by mixing materials in this group with alkali metals. Explosive combination can occur with strong oxidizing agents, metal salts, peroxides, and sulfides.
Fire Hazard
Flash point data for Zidovudine are not available; however, Zidovudine is probably combustible.
Pharmaceutical Applications
An analog of thymidine formulated for oral or intravenous use.
Biochem/physiol Actions
Reverse transcriptase inhibitor active against HIV-1 virus.
Mechanism of action
Zidovudine (AZT , ZDV) is an analogue of thymidine in which the azido group is substituted at the 3-carbon atom of the dideoxyribose moiety. It is active against RNA tumor viruses (retroviruses) that are the causative agents of AIDS and T-cell leukemia. Retroviruses, by virtue of RT, direct the synthesis of a provirus (DNA copy of a viral RNA genome). Proviral DNA integrates into the normal cell DNA, leading to the HIV infection. Zidovudine is converted to 5′-mono-, di-, and triphosphates by the cellular thymidine kinase. These phosphates are then incorporated into proviral DNA, because RT uses ZDV-triphosphate as a substrate. This process prevents normal 5′,3′-phosphodiester bonding, resulting in termination of DNA chain elongation because of the presence of an azido group in ZDV. The multiplication of HIV is halted by selective inhibition of RT and, thus, viral DNA polymerase by ZDV-triphosphate at the required dose concentration. Zidovudine is a potent inhibitor of HIV-1, but it also inhibits HIV-2 and EBV.
Pharmacokinetics
Oral absorption: 65%
Cmax 300 mg twice daily: 2.3 mg/L
Plasma half-life: 1.1 h
Volume of distribution: 1.6 L/kg
Plasma protein binding; 34–38%
Absorption and distribution
It is absorbed rapidly and almost completely following oral administration. Absorption is not significantly affected by food. It appears to undergo widespread body distribution. CNS penetration is fairly good. The semen:plasma ratio varies from 0.95 to 13.5 (mean 5.9). It is secreted into breast milk.
Metabolism and excretion
Following hepatic metabolism (glucuronidation), elimination is primarily renal. After oral administration, urinary recovery of zidovudine and its glucuronide metabolite accounted for 14% and 74% respectively of the dose, with a total urinary recovery of 90%.
In severe renal impairment, clearance was about half that reported in subjects with normal renal function Accumulation may occur in patients with hepatic impairment due to decreased glucuronidation.
Clinical Use
Treatment of HIV infection in adults and children (in combination with
other antiretroviral drugs)
Reduction of maternal transmission of HIV to the fetus
Side effects
In common with other drugs in this class, use has been associated
with episodes of fatal and non-fatal lactic acidosis
and hepatomegaly with steatosis. Careful clinical evaluation
is needed in patients with evidence of hepatic abnormality.
Myelosuppression may occur within the first 4–6 weeks of
therapy. Hematological parameters should be monitored during
this period, with prompt dose modification or switch if
abnormalities are observed. Treatment with reduced doses
may be attempted in some patients once bone marrow recovery
has been observed. Myopathy is rarely seen with the use
of the current dosing regimens.
Co-administration with drugs known to cause nephrotoxicity,
cytotoxicity or which interfere with red or white blood
cell number and function may increase the risk of toxicity.
Probenecid and trimethoprim may reduce renal clearance
of zidovudine, and other drugs that are metabolized by
glucuronidation may interfere with its metabolism.
Safety Profile
Moderately toxic by intravenousroute. Human systemic effects by ingestion: aplasticanemia, changes in blood cell count, convulsions or effect on seizure threshold, headache, nails, retinal changes.Human mutation data reported.
Synthesis
Zidovudine is 3-azido-3-deoxytimidine (36.1.26), is synthesized from
1-(2-deoxy-5-O-trityl-β-D-lyxosyl)thymine, which is treated with methansulfonyl chloride in pyridine to make the corresponding mesylate 36.1.24. Replacing the methyl group
with an azide group using lithium azide in dimethylformamaide makes the product 36.1.25
with inverted configuration at C3 of the furanosyl ring. Heating this in 80% acetic acid
removes the trityl protection, giving zidovudine.
Veterinary Drugs and Treatments
In veterinary medicine, zidovudine may be useful for treating feline
immunodeficiency virus (FIV) or feline leukemia virus (FeLV).
While zidovudine can reduce the viral load in infected cats and improve
clinical signs, it may not alter the natural course of the disease
to a great extent.
Drug interactions
Potentially hazardous interactions with other drugs
Antibacterials: absorption reduced by clarithromycin;
avoid concomitant use with rifampicin.
Antiepileptics: phenytoin levels may be raised
or lowered; concentration possibly increased by
valproate (increased risk of toxicity).
Antifungals: concentration increased by fluconazole.
Antivirals: profound myelosuppression with
ganciclovir and valganciclovir - avoid if possible;
increased risk of granulocytopenia with nevirapine;
increased risk of anaemia with ribavirin - avoid;
effects of stavudine inhibited - avoid concomitant
use; concentration reduced by tipranavir.
Orlistat: absorption possibly reduced by orlistat.
Probenecid: excretion reduced by probenecid,
increased risk of toxicity.
Metabolism
Zidovudine is metabolised intracellularly to the antiviral
triphosphate. It is also metabolised in the liver, mainly to
the inactive glucuronide, and is excreted in the urine as
unchanged drug and metabolite.
The 5'-glucuronide of zidovudine is the major metabolite
in both plasma and urine, accounting for approximately
50-80% of the administered dose eliminated by renal
excretion. There is substantial accumulation of this
metabolite in renal failure.
Renal clearance of zidovudine greatly exceeds creatinine
clearance, indicating that significant tubular secretion
takes place.
References
1) Yarchoan?et al. (1989),?Clinical Pharmacology of 3-Azido-2’,3’-Dideoxythymidine (Zidovudine) and Related Dideoxynucleosides; N. Engl. J. Med.?321?726
2) D’Andrea?et al.?(2008),?AZT: an old drug with new perspectives; Curr. Clin. Pharmacol.?3?20
3) Yu?et al. (2015),?Small molecules enhance CRISPR genome editing in pluripotent stem cells; Cell Stem Cell.?16?142
Check Digit Verification of cas no
The CAS Registry Mumber 30516-87-1 includes 8 digits separated into 3 groups by hyphens. The first part of the number,starting from the left, has 5 digits, 3,0,5,1 and 6 respectively; the second part has 2 digits, 8 and 7 respectively.
Calculate Digit Verification of CAS Registry Number 30516-87:
(7*3)+(6*0)+(5*5)+(4*1)+(3*6)+(2*8)+(1*7)=91
91 % 10 = 1
So 30516-87-1 is a valid CAS Registry Number.
InChI:InChI=1/C10H13N5O4/c1-5-3-15(10(18)12-9(5)17)8-2-6(13-14-11)7(4-16)19-8/h3,6-8,16H,2,4H2,1H3,(H,12,17,18)/t6-,7+,8-/m0/s1
30516-87-1Relevant articles and documents
Ester prodrugs of zidovudine
Kawaguchi,Ishikawa,Seki,Juni
, p. 531 - 533 (1990)
Ten novel ester prodrugs of zidovudine (azidothymidine; AZT) were synthesized with aliphatic acids (acetic-stearic), and the enzymatic regeneration of AZT from the prodrugs was investigated both in vitro and in vivo. The enzymatic hydrolysis rates of the AZT esters in the presence of mouse enzyme systems (plasma, liver, and intestine, and kidney) were highly dependent on the lengths of the acyl chains of the prodrugs. The caprate or caprylate of AZT showed the highest reactivity to three of the four enzyme systems; either the decrease or the increase in the acyl chain length resulted in the decrease of the reactivity to the enzymes. Zidovudine (AZT) and three of the prodrugs (acetate, caprate, and stearate) were administered to mice intraperitoneally, and the plasma concentrations of AZT and a corresponding prodrug were measured. The AZT concentrations in plasma following the acetate administration rapidly decreased with a half-life of 14.5 min. This tendency is similar to that shown in direct AZT administration. On the other hand, the concentrations following the caprate or stearate administration decreased slowly and were maintained for as long as 4 h after dosing. The prodrug concentrations in plasma after the prodrug administration were under the detection limit (0.01 μg/mL), except for acetate. The absence of the caprate and stearate in plasma may be attributed to the high hydrophobicity or favorable tissue distribution of the ester derivatives.
3'-Azido-3'-deoxy-5'-O-isonicotinoylthymidine: a novel antiretroviral analog of zidovudine. II. Stability in aqueous media and experimental and theoretical ionization constants.
Teijeiro, Silvina A,Raviolo, Monica A,Motura, Marisa I,Brinon, Margarita C
, p. 1789 - 1803 (2003)
Degradation of 3'-azido-3'-deoxy-5'-O-isonicotinoylthymidine (AZT-Iso), an antiretroviral derivative of zidovudine, was investigated in buffer pH 7.4, mu = 300 mOsm at 37, 50 and 60 degrees C, and in water (pH 6.6, 37 degrees C), giving zidovudine (AZT) and isonicotinic acid (INA) as products. The rate constants were determined by reversed-phase HPLC showing pseudo-first-order kinetics related to the residual amount of AZT-Iso. In this way, the studied compound was demonstrated to be 153 times more stable in water than in buffer solution at 37 degrees C. The analytical method was conveniently validated demonstrating to be a rapid and accurate stability-indicating technique. In addition, experimental and theoretical values of pKa were determined.
A novel synthesis of AZT
Gauthier, Christine,Ramondenc, Yvan,Plé, Gérard
, p. 7513 - 7517 (2001)
A novel synthesis of AZT has been achieved from two commercial available products acetaldehyde and D-mannitol. The originality of the synthesis consists of using the powerful monovinylogation reagent, the 2-lithio-1-trimethylsiloxyethylene, and to introduce the thymine moiety and to build the furanose ring in the same and last step.
Modular click chemistry libraries for functional screens using a diazotizing reagent
Meng, Genyi,Guo, Taijie,Ma, Tiancheng,Zhang, Jiong,Shen, Yucheng,Sharpless, Karl Barry,Dong, Jiajia
, p. 86 - 89 (2019/11/13)
Click chemistry is a concept in which modular synthesis is used to rapidly find new molecules with desirable properties1. Copper(i)-catalysed azide–alkyne cycloaddition (CuAAC) triazole annulation and sulfur(vi) fluoride exchange (SuFEx) catalysis are widely regarded as click reactions2–4, providing rapid access to their products in yields approaching 100% while being largely orthogonal to other reactions. However, in the case of CuAAC reactions, the availability of azide reagents is limited owing to their potential toxicity and the risk of explosion involved in their preparation. Here we report another reaction to add to the click reaction family: the formation of azides from primary amines, one of the most abundant functional groups5. The reaction uses just one equivalent of a simple diazotizing species, fluorosulfuryl azide6–11 (FSO2N3), and enables the preparation of over 1,200 azides on 96-well plates in a safe and practical manner. This reliable transformation is a powerful tool for the CuAAC triazole annulation, the most widely used click reaction at present. This method greatly expands the number of accessible azides and 1,2,3-triazoles and, given the ubiquity of the CuAAC reaction, it should find application in organic synthesis, medicinal chemistry, chemical biology and materials science.
Antimalarial naphthoquinones. Synthesis via click chemistry, in vitro activity, docking to PfDHODH and SAR of lapachol-based compounds
Brand?o, Geraldo Célio,Rocha Missias, Franciele C.,Pereira, Guilherme Rocha,Arantes, Lucas Miquéias,Soares, Luciana Ferreira,Braga de Oliveira, Alaide,Roy, Kuldeep K.,Doerksen, Robert J.
, p. 191 - 205 (2018/05/02)
Lapachol is an abundant prenyl naphthoquinone occurring in Brazilian Bignoniaceae that was clinically used, in former times, as an antimalarial drug, despite its moderate effect. Aiming to search for potentially better antimalarials, a series of 1,2,3-triazole derivatives was synthesized by chemical modification of lapachol. Alkylation of the hydroxyl group gave its propargyl ether which, via copper-catalyzed cycloaddition (CuAAC) click chemistry with different organic azides, afforded 17 naphthoquinonolyl triazole derivatives. All the synthetic compounds were evaluated for their in vitro activity against chloroquine resistant Plasmodium falciparum (W2) and for cytotoxicity to HepG2 cells. Compounds containing the naphthoquinolyl triazole moieties showed higher antimalarial activity than lapachol (IC50 123.5 μM) and selectivity index (SI) values in the range of 4.5–197.7. Molecular docking simulations of lapachol, atovaquone and all the newly synthesized compounds were carried out for interactions with PfDHODH, a mitochondrial enzyme of the parasite respiratory chain that is essential for de novo pyrimidine biosynthesis. Docking of the naphthoquinonolyl triazole derivatives to PfDHODH yielded scores between ?9.375 and ?14.55 units, compared to ?9.137 for lapachol and ?12.95 for atovaquone and disclosed the derivative 17 as a lead compound. Therefore, the study results show the enhancement of DHODH binding affinity correlated with improvement of SI values and in vitro activities of the lapachol derivatives.