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Preparation of 1° Amines: Azide Synthesis01:22

Preparation of 1° Amines: Azide Synthesis

4.0K
Direct alkylation of ammonia produces polyalkylated amines, along with a quaternary ammonium salt. To exclusively prepare primary amines, the azide synthesis method can be used.
Azide ions act as good nucleophiles and react with unhindered alkyl halides to form alkyl azides. Alkyl azides do not participate in further nucleophilic substitution reactions, thereby eliminating the chances of polyalkylated products. Alkyl azides are reduced by hydride-based reducing agents, like lithium aluminum...
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Preparation of Amides01:29

Preparation of Amides

3.2K
Amides are synthesized by treating carboxylic acids with amines in the presence of dehydrating agents like dicyclohexylcarbodiimide (DCC).
The DCC-promoted synthesis of amides begins with the protonation of DCC by carboxylic acid. The protonation makes it a better acceptor. Next, the addition of carboxylate to the protonated carbodiimide gives a reactive acylating agent.
Subsequently, the amine acts as a nucleophile that attacks the acylating agent to form a tetrahedral intermediate. In the...
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Preparation of 1° Amines: Hofmann and Curtius Rearrangement Overview01:07

Preparation of 1° Amines: Hofmann and Curtius Rearrangement Overview

3.3K
In the presence of an aqueous base and a halogen, primary amides can lose the carbonyl (as carbon dioxide) and undergo rearrangement to form primary amines. This reaction, called the Hofmann rearrangement, can produce primary amines (aryl and alkyl) in high yields without contamination by secondary and tertiary amines.
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Preparation of 1° Amines: Gabriel Synthesis01:28

Preparation of 1° Amines: Gabriel Synthesis

3.6K
Direct alkylation is not a suitable method for synthesizing amines because it produces polyalkylated products. Gabriel synthesis is the most preferred method to exclusively make primary amines. The method uses phthalimide, which contains a protected form of nitrogen that participates in alkylation only once to predominantly give primary amines.
Strong bases like NaOH or KOH deprotonate the phthalimide to form the corresponding anion, which acts as a nucleophile. Further, the anion attacks an...
3.6K
Diazonium Group Substitution with Halogens and Cyanide: Sandmeyer and Schiemann Reactions01:20

Diazonium Group Substitution with Halogens and Cyanide: Sandmeyer and Schiemann Reactions

1.9K
Arenediazonium substitution reactions occur when the diazonium group is substituted by various functional groups such as halides, hydroxyl, nitrile, etc. For instance, arenediazonium salts react with copper(I) salts of chloride, bromide, or cyanide to form corresponding aryl chlorides, bromides, and nitriles. These reactions are named Sandmeyer reactions. Although the mechanism of this reaction is complicated, as illustrated in Figure 1, they are believed to progress via an aryl copper...
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Preparation of 1° Amines: Hofmann and Curtius Rearrangement Mechanism01:26

Preparation of 1° Amines: Hofmann and Curtius Rearrangement Mechanism

3.5K
The Hofmann and Curtius rearrangement reactions can be applied to synthesize primary amines from carboxylic acid derivatives such as amides and acyl azides. In the Hofmann rearrangement, a primary amide undergoes deprotonation in the presence of a base, followed by halogenation to generate an N-haloamide. A second proton abstraction produces a stabilized anionic species, which rearranges to an isocyanate intermediate via an alkyl group migration from the carbonyl carbon to the neighboring...
3.5K

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Related Experiment Video

Updated: Jul 27, 2025

Microwave-Assisted Preparation of 1-Aryl-1H-pyrazole-5-amines
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Microwave-Assisted Preparation of 1-Aryl-1H-pyrazole-5-amines

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Imidazopyridine Amides: Synthesis,

Rana Abdelaziz1, Justin M Di Trani2, Henok Sahile3

  • 1Institut Für Pharmazie, Martin-Luther-Universität Halle-Wittenberg, Halle (Saale) 06120, Germany.

ACS Omega
|June 5, 2023
PubMed
Summary
This summary is machine-generated.

Q203, an imidazopyridine amide (IPA), targets the mycobacterial electron transport chain. Researchers synthesized 27 analogues to understand IPA's mechanism, finding selectivity for mycobacteria over human mitochondria.

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Preparation of Enantiopure Non-Activated Aziridines and Synthesis of Biemamide B, D, and epiallo-Isomuscarine
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Area of Science:

  • Biochemistry
  • Medicinal Chemistry
  • Microbiology

Background:

  • Q203 (telacebec) is an imidazopyridine amide (IPA) that inhibits the mycobacterial respiratory CIII2CIV2 supercomplex.
  • Understanding the molecular mechanism of action of IPAs is crucial for developing new anti-mycobacterial agents.

Purpose of the Study:

  • To synthesize and evaluate 27 novel IPA analogues for their inhibitory activity against the mycobacterial electron transport chain (ETC).
  • To investigate the structure-activity relationships (SAR) of these compounds.
  • To assess the selectivity of IPAs against mycobacterial ETC compared to mitochondrial ETC.

Main Methods:

  • A seven-step synthetic scheme was employed to prepare 27 IPA analogues.
  • Oxygen consumption assays were used to determine the inhibitory potency of compounds against purified Mycobacterium smegmatis CIII2CIV2.
  • In vitro growth inhibition assays were performed against Mycobacterium tuberculosis.

Main Results:

  • The IC50 values for Q203 and compound 27 against M. smegmatis CIII2CIV2 were 99 ± 32 nM and 441 ± 138 nM, respectively.
  • All synthesized IPAs, including Q203, demonstrated selectivity by not inhibiting the mitochondrial ETC.
  • A perfect correlation between in vitro CIII2CIV2 inhibition and Mycobacterium tuberculosis growth inhibition was not observed.

Conclusions:

  • The synthesized IPA analogues generally support the SAR derived from the Q203-bound M. smegmatis CIII2CIV2 structure.
  • The observed lack of perfect correlation between CIII2CIV2 inhibition and cellular activity suggests potential resistance mechanisms in mycobacteria.
  • Further research into mycobacterial resistance mechanisms is warranted to fully elucidate the activity of these compounds.