4448-87-7

Upstream product

• 111-36-4 n-butyl isocyanide 
• 871-71-6 N-butylformamide 
• 109-73-9 N-butylamine 
• 2769-64-4 n-butyl isonitrile 

Downstream Products

• 93334-97-5 1,1,2-Trimethyl-4-n-butyl-selenosemicarbazid 
• 95074-41-2 4-n-Butyl-1-phenyl-selenosemicarbazid 
• 1453815-70-7 5-benzylselanyl-1-butyl-1H-tetrazole 
• 1453815-71-8 1-butyl-5-(3,5-dinitrobenzylselanyl)-1H-tetrazole 
• 95982-02-8 Benzaldehyd-<2-Methyl-4-n-butyl-selenosemicarbazon> 
• 96130-88-0 Benzaldehyd-<4-n-butyl-selenosemicarbazon> 
• 95983-41-8 4-n-Butyl-1-benzoyl-selenosemicarbazid 

Relevant academic research and scientific papers

A tripodal tris-selenourea anion transporter matches the activity of its thio- analogue but shows distinct selectivity*

We report the synthesis of a tripodal tris-selenourea transporter scaffold. The Cl? and NO?3 transport activity of the compound has been compared extensively with the analogous oxo- and thiourea compounds. We found that the selenourea demonstrates remarkably similar transport efficacy and mechanistic properties to the equivalent thiourea, but demonstrates flipped selectivity for Cl? over NO?3.

Synthesis and leishmanicidal activity of novel urea, thiourea, and selenourea derivatives of diselenides

A novel series of thirty-one N-substituted urea, thiourea, and selenourea derivatives containing diphenyldiselenide entities were synthesized, fully characterized by spectroscopic and analytical methods, and screened for their in vitro leishmanicidal activities. The cytotoxic activity of these derivatives was tested against Leishmania infantum axenic amastigotes, and selectivity was assessed in human THP-1 cells. Thirteen of the synthesized compounds showed a significant antileishmanial activity, with 50% effective concentration (EC50) values lower than that for the reference drug miltefosine (EC50, 2.84 M). In addition, the derivatives 9, 11, 42, and 47, with EC50 between 1.1 and 1.95 M, also displayed excellent selectivity (selectivity index ranged from 12.4 to 22.7) and were tested against infected macrophages. Compound 11, a derivative with a cyclohexyl chain, exhibited the highest activity against intracellular amastigotes, with EC50 values similar to those observed for the standard drug edelfosine. Structure-activity relationship analyses revealed that N-aliphatic substitution in urea and selenourea is recommended for the leishmanicidal activity of these analogs. Preliminary studies of the mechanism of action for the hit compounds was carried out by measuring their ability to inhibit trypanothione reductase. Even though the obtained results suggest that this enzyme is not the target for most of these derivatives, their activity comparable to that of the standards and lack of toxicity in THP-1 cells highlight the potential of these compounds to be optimized for leishmaniasis treatment.

Thermal stability and decomposition of urea, thiourea and selenourea analogous diselenide derivatives

The fusion and thermal decomposition of thirty-three diselenide compounds with a urea, thiourea or selenourea group linked with different aliphatic or aromatic substituents have been studied by thermogravimetry, differential scanning calorimetry and mass spectrometry in order to perform comparative thermal stability studies among analogs. A relationship has been found between stability and a series of effects which occur in the compound structures. Analysis of the thermal data indicated that: (a) in general, compounds with a urea or selenourea group are more stable than those with a thiourea group; (b) no difference in stability exists when an aromatic or aliphatic group is linked to the thiourea group but when linked to the urea or selenourea groups, stability does differ; (c) selenourea compounds with aliphatic chain are the most unstable; and (d) the nature of the substituent located on the benzyl ring has no effects on thermal stability. Therefore, criteria for the selection of substituents can be established in order to improve the stability of these drugs. In addition, the mass spectral fragmentation in comparison with thermal analytical data helps in confirming the thermal behavior of the compounds.

Regioselective one-pot three component synthesis of chiral 2-iminoselenazolines under sonication

A one-pot multi component reaction of selenoureas, which are in situ generated from l-amino esters and isoselenocyanates, with α-bromoketone under ultrasonication. Selenourea and α-bromoketones formed 2-iminoselenazoles through a Hantzsch selenazole-type reaction. The steric effect of the α-substituted bromoketones on the rate of the tandem reaction was studied to understand the reaction mechanism by isolating the key reaction intermediate, 2-iminoselenol.

One-pot synthesis of 1-substituted-5-alkylselanyl-1H-tetrazoles from isoselenocyanates: Unexpected formation of N-alkyl-N-arylcyanamides and (Z)-Se-alkyl-N-cyano-N,N′-diarylisoselenoureas

1-Substituted-5-alkylsulfanyl-1H-tetrazoles are well known class of organic substances with various applications in medicinal chemistry or photographic industry. Their selenium analogues, 1-substituted-5-alkylselanyl-1H-tetrazoles are, however, much less explored because of the lack of suitable methods for their preparation. In this work we investigated the synthesis of 1-alkyl/aryl-5-alkylselanyl-1H-tetrazoles from synthetically available alkyl/arylisoselenocyanates. One-pot reactions of arylisoselenocyanates with sodium azide and alkylating agent led to the target 5-alkylselanyl-1-aryl-1H- tetrazoles but also to interesting side products, namely N-alkyl-N- arylcyanamides and (Z)-Se-alkyl-N-cyano-N,N′-diarylisoselenoureas. Nevertheless, when alkylisoselenocyanates were utilized as the substrates, the reactions led exclusively to the formation of 1-alkyl-5-alkylselanyl-1H- tetrazoles in good yields. This simple one-pot procedure brings new possibilities for the preparation of variously substituted selenium compounds. It also opens the way to further investigations of selenium isosteres of the widely utilized 5-thiotetrazole moiety in biomedical applications.

One-pot synthesis of selenoureas and selenocarbamates via selenation of isocyanates with bis(dimethylaluminum) selenide

Isocyanates were efficiently selenated by the reaction with bis(dimethylaluminum) selenide to give the corresponding isoselenocyanates. One-pot synthesis of unsymmetrical selenoureas and selenocarbamates was achieved in high yields by the subsequent addit