Streptomycin

Base Information Edit

Chemical Name:Streptomycin
CAS No.:57-92-1
Deprecated CAS:12672-24-1,82958-69-8,47814-83-5,47816-81-9,364062-67-9,47814-83-5,47816-81-9
Molecular Formula:C21H39N7O12
Molecular Weight:581.58
Hs Code.:2941200000
European Community (EC) Number:200-355-3
UNII:Y45QSO73OB
DSSTox Substance ID:DTXSID4023597
Nikkaji Number:J4.500D
Wikipedia:Streptomycin
Wikidata:Q192717
NCI Thesaurus Code:C61952
RXCUI:10109
Metabolomics Workbench ID:43315
ChEMBL ID:CHEMBL372795
Mol file:57-92-1.mol

Synonyms:Estreptomicina CEPA;Estreptomicina Clariana;Estreptomicina Normon;Strepto Fatol;Strepto Hefa;Strepto-Fatol;Strepto-Hefa;Streptomycin;Streptomycin Grünenthal;Streptomycin Sulfate;Streptomycin Sulfate (2:3) Salt;Streptomycin Sulphate;Streptomycine Panpharma

Suppliers and Price of Streptomycin

Supply Marketing:Edit

Business phase:: The product has achieved commercial mass production^*data from LookChem market partment

Manufacturers and distributors:

Manufacture/Brand
Chemicals and raw materials
Packaging
price

Usbiological
Streptomycin
500ul
$ 393.00

TRC
StreptomycinA
500mg
$ 475.00

Matrix Scientific
Streptomycin A
100g
$ 1954.00

DC Chemicals
streptomycin >99%
1 g
$ 800.00

DC Chemicals
streptomycin >99%
100 mg
$ 200.00

DC Chemicals
streptomycin >99%
250 mg
$ 400.00

Crysdot
Agrimycin 97%
5g
$ 420.00

Crysdot
Agrimycin 97%
1g
$ 140.00

Biorbyt Ltd
Streptomycin
500 μg
$ 957.10

Biorbyt Ltd
Streptomycin
100 μg
$ 635.80

Total 79 raw suppliers

Chemical Property of Streptomycin Edit

Chemical Property:

Appearance/Colour:Crystalline powder
Melting Point:194 °C
Refractive Index:1.6800 (estimate)
Boiling Point:948.247 °C at 760 mmHg
PKA:pKa 7.84(H2O t = 25 I = 0.1) (Uncertain);11.54(H2O t = 25 I = 0.1) (Uncertain);>12(H2O t = 25 I = 0.1) (Uncertain)
Flash Point:527.281 °C
PSA：331.43000
Density:1.982 g/cm³
LogP:-4.96900
Storage Temp.:2-8°C
XLogP3:-8
Hydrogen Bond Donor Count:12
Hydrogen Bond Acceptor Count:15
Rotatable Bond Count:9
Exact Mass:581.26566970
Heavy Atom Count:40
Complexity:940

Purity/Quality:

99% , ^*data from raw suppliers

Streptomycin ^*data from reagent suppliers

Safty Information:

Pictogram(s):
Hazard Codes:

MSDS Files:

SDS file from LookChem

Total 1 MSDS from other Authors

Useful:

Chemical Classes:Other Uses -> Pharmaceuticals
Drug Classes:Antituberculosis Agents
Canonical SMILES:CC1C(C(C(O1)OC2C(C(C(C(C2O)O)N=C(N)N)O)N=C(N)N)OC3C(C(C(C(O3)CO)O)O)NC)(C=O)O
Isomeric SMILES:C[C@H]1[C@@]([C@H]([C@@H](O1)O[C@@H]2[C@H]([C@@H]([C@H]([C@@H]([C@H]2O)O)N=C(N)N)O)N=C(N)N)O[C@H]3[C@H]([C@@H]([C@H]([C@@H](O3)CO)O)O)NC)(C=O)O
Recent ClinicalTrials:Ciprofloxacin Versus an Aminoglycoside Followed by Ciprofloxacin for Bubonic Plague
Description The antibiotic streptomycin is an important and effective chemical for the management of bacterial diseases of fruit trees (especially apple), woody ornamentals, and vegetables. Streptomycin was initially discovered in 1944 and was one of the first antibiotics to be utilized in clinical medicine to control human diseases, and is still important as a feed amendment for growth promotion in agricultural animals. The widespread and diverse usage of streptomycin has contributed to the currently observed global streptomycin resistance (SmR) problem. This problem is especially critical in plant disease management, as there are few alternatives to streptomycin available and, as a consequence of increased usage, SmR has been increasingly observed among bacterial plant pathogens.
Uses Control of bacterial shot-hole, bacterial rots, bacterial canker, bacterial wilts, fire blight, and other diseases caused by gram-positive species of bacteria in pome fruit, stone fruit, citrus fruit, olives, vegetables, potatoes, tobacco, cotton, and ornamentals. Chlorosis may occur on grapes, pears, peaches, and some ornamentals. Formulation types WP; Liquid. Incompatible with pyrethrins and alkaline materials. A mixture of streptomycin and oxytetracycline is highly effective for the control of bacterial canker of peach, citrus canker, soft rot of vegetables, and various other bacterial diseases. Selected tradenames “Agrimycin 17” (sesquisulfate); “AS-50” (sesquisulfate). Streptomycin is the most commonly utilized bactericidal antibiotic for the management of plant pathogens and has been used most frequently on apple, pear, sweet pepper, and ornamental trees.
Indications Streptomycin, an aminoglycoside antibiotic was the first drug shown to reduce tuberculosis mortality. Streptomycin is bactericidal against M. tuberculosis in vitro but is inactive against intracellular organisms. Most M. tuberculosis strains and nontuberculosis species, such as M. kansasii and M. aviumintracellulare, are sensitive. Spontaneous resistance to streptomycin, seen in approximately 1 in 106 tubercle bacilli, is related to a point mutation that involves the gene (rpsl or rrs) that encodes for ribosomal proteins and binding sites.About 80% of strains that are resistant to isoniazid and rifampin are also resistant to streptomycin.
Therapeutic Function Antitubercular
Clinical Use Streptomycin is indicated as a fourth drug in combination with isoniazid, rifampin, and pyrazinamide in patients at high risk for drug resistance. It is also used in the treatment of streptomycin-susceptible MDR tuberculosis. Tuberculosis (in combination with other antituberculosis drugs) Infections caused by M. kansasii (in combination with other antimycobacterial agents) Plague and tularemia, including tularemia pneumonia Bacterial endocarditis (in combination with a penicillin) Brucellosis Whipple’s disease (in combination with other antibiotics) The most important use of streptomycin is in the treatment of tuberculosis . Depression of vestibular function by streptomycin has been used in the treatment of patients suffering from Ménière’s disease.
Drug interactions Potentially hazardous interactions with other drugs Antibacterials: increased risk of nephrotoxicity with colistimethate or polymyxins and possibly cephalosporins; increased risk of ototoxicity and nephrotoxicity with capreomycin or vancomycin. Ciclosporin: increased risk of nephrotoxicity. Cytotoxics: increased risk of nephrotoxicity and ototoxicity with platinum compounds. Loop diuretics: increased risk of ototoxicity. Muscle relaxants: enhanced effects of nondepolarising muscle relaxants and suxamethonium. Parasympathomimetics: neostigmine and pyridostigmine antagonised by aminoglycosides. Tacrolimus: increased risk of nephrotoxicity.

Technology Process of Streptomycin

There total 1 articles about Streptomycin which guide to synthetic route it. The literature collected by LookChem mainly comes from the sharing of users and the free literature resources found by Internet computing technology. We keep the original model of the professional version of literature to make it easier and faster for users to retrieve and use. At the same time, we analyze and calculate the most feasible synthesis route with the highest yield for your reference as below:

synthetic route:

Reference yield: