The focus of this study was the development of a new synthetic method for quinazolinones based on the principles of Green Chemistry. Quinazolinones were synthesized from 2‐aminobenzamide using methanol as both the C1 source and a green solvent in the presence of base Cs2CO3. Additionally, a commercially available, economical copper complex was used as a catalyst in the reaction. The desired products were achieved in moderate to high yield with up to 99 % isolated yield.
The emergence of SARS-CoV-2 in December
2019 has become a global
issue due to the continuous upsurge in patients and the lack of drug
efficacy for treatment. SARS-CoV-2 3CLPro is one of the
most intriguing biomolecular targets among scientists worldwide for
developing antiviral drugs due to its relevance in viral replication
and transcription. Herein, we utilized computer-assisted drug screening
to investigate 326 natural products from Thai traditional plants using
structure-based virtual screening against SARS-CoV-2 3CLPro. Following the virtual screening, the top 15 compounds based on
binding energy and their interactions with key amino acid Cys145 were
obtained. Subsequently, they were further evaluated for protein–ligand
complex stability via molecular dynamics simulation
and binding free energy calculation using molecular mechanics Poisson–Boltzmann
surface area (MM-PBSA) approaches. Following drug-likeness and ADME/Tox
assessments, seven bisbenzylisoquinolines were obtained, including
neferine (3), liensinine (4), isoliensinine
(5), dinklacorine (8), tiliacorinine (13), 2′-nortiliacorinine (14), and yanangcorinine
(15). These compounds computationally showed a higher
binding affinity than native N3 and GC-373 inhibitors and attained
stable interactions on the active site of 3CLpro during
100 ns in molecular dynamics (MD) simulation. Moreover, the in vitro enzymatic assay showed that most bisbenzylisoquinolines
could experimentally inhibit SARS-CoV-2 3CLPro. To our
delight, isoliensinine (5) isolated from Nelumbo
nucifera demonstrated the highest inhibition of protease
activity with the IC50 value of 29.93 μM with low
toxicity on Vero cells. Our findings suggested that bisbenzylisoquinoline
scaffolds could be potentially used as an in vivo model for the development of effective anti-SARS-CoV-2 drugs.
In this work, we successfully synthesized high thermal sTable 1,n-bis(N-(N′-butylimidazolium)alkane bishexafluorophosphates (1,n-bis[Bim][PF6], n = 4, 6, 8, and 10) catalysts in 55–70% yields from imidazole which were applied as non-toxic DILs catalysts with 1-butanol as initiator for the bulk ROP of ε-caprolactone (CL) in the varied ratio of CL/nBuOH/1,4-bis[Bim][PF6] from 200/1.0/0.25‒4.0 to 700/1.0/0.25‒4.0 by mol%. The result found that the optimal ratio of CL/nBuOH/1,4-bis[Bim][PF6] 400/1.0/0.5 mol% at 120 °C for 72 h led to the polymerization conversions higher than 95%, with the molecular weight (Mw) of PCL 20,130 g mol−1 (Đ~1.80). The polymerization rate of CL increased with the decreasing linker chain length of ionic liquids. Moreover, the mechanistic study was investigated by DFT using B3LYP (6–31G(d,p)) as basis set. The most plausible mechanism included the stepwise and coordination insertion in which the alkoxide insertion step is the rate-determining step.
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