Adsorption behavior of amphetamine on the inorganic BC3 nanotube and nanosheet: DFT studies

“…These binding energies as well as the Δ G and Δ H values are in agreement with literature on potential sensors to detect AMP. 22,24,26,64,66…”

Computational study of the interaction of the psychoactive amphetamine with 1,2-indanedione and 1,8-diazafluoren-9-one as fingerprinting reagents

“…These binding energies as well as the Δ G and Δ H values are in agreement with literature on potential sensors to detect AMP. 22,24,26,64,66…”

Computational study of the interaction of the psychoactive amphetamine with 1,2-indanedione and 1,8-diazafluoren-9-one as fingerprinting reagents

“…11 [ 286 , 287 ]. This BC 3 nanosheet (NS) and nanotube (NT) was further studied by A. R. Moosavi-zare et al to sense an illicit CNS stimulant amphetamine (AA) which was also reported to be adsorbed by pristine and Si, Ge doped C 60 fullerenes [ 257 , 288 ]. It was observed that the BC 3 NT adsorbed AA more strongly than the BC 3 NT with an adsorption energy of −15.5 kcal/mol where it was −10.7 kcal/mol for the BC 3 NS.…”

The recent advancement of low-dimensional nanostructured materials for drug delivery and drug sensing application: A brief review

“…Amphetamine : 2016 Determination of 1-phenyl-2-propanone (P2P) by HS-GC/MS in a material sold as “wet amphetamine” [ 9 ]; Amphetamine and derivatives in natural weight loss pills and dietary supplements by CE-MS/MS [ 10 ]; 2017 [ 11 ]; Accelerated quantification of amphetamine enantiomers using chiral liquid chromatography and on-line column-switching coupled with tandem mass spectrometry [ 12 ]; Identification of specific markers for amphetamine synthesized from the pre-precursor APAAN following the Leuckart route and retrospective search for APAAN markers in profiling databases from Germany and the Netherlands [ 13 ]; new approaches to gather information about the clandestine production of Amphetamine [ 14 ]; ‘APAAN in the neck’ - a reflection on some novel impurities found in seized materials containing amphetamine in Ireland during routine forensic analysis [ 15 ]; impurity profiling of the byproducts of the APAAN to P2P and AMS to P2P amphetamine synthesis to differentiate the synthesis route [ 16 ]; monitoring of the amphetamine-like substances in dietary supplements by LC-PDA and LC-MS/MS [ 17 ]; amphetamine and derivatives by DART- DMS [ 18 ]; investigation of the interaction of amphetamine with the pristine, B, Al, Ga (group IIIA), Si, and Ge (IIV group) doped C-60 fullerenes for use as sensors for amphetamine drug detection [ 19 ]; 2018 development of amphetamine-ion-selective microelectrodes using electrochemical polymerization and microfabrication technologies [ 20 ]; high-performance ion-selective microelectrode for the detection of amphetamine [ 21 ]; characterization of aqueous waste produced during the clandestine production of amphetamine by SPE GC-MS following the spectrometry and CE with contactless conductivity detection [ 22 ]; adsorption of amphetamine on BC3 nanosheet and nanotube for drug detection [ 23 ]; identification of specific markers for amphetamine synthesized from the pre-precursor APAAN following the Leuckart route and retrospective search for APAAN markers in profiling databases from Germany and the Netherlands using mass spectra, high resolution MS and NMR data [ 24 ]; impact of different storage conditions on the stability of amphetamine impurity profiles [ 25 ]; 2019 resin for enantio-selective extraction of R-amphetamine [ 26 ].…”

Interpol review of controlled substances 2016–2019