Biological Screening Research Articles

Transition metal based coordination compounds of Schiff base derived from drug molecules: Synthesis, Spectroscopic and In-Vitro biological screening

Transition metal based coordination compounds of Schiff base derived from drug molecules: Synthesis, Spectroscopic and In-Vitro biological screening

Redefining Chronic Disease Care: Unleashing the Potential of Phytomedicines.

Phytomedicines represent a diverse array of plant-derived compounds renowned for their therapeutic potential. Traditionally, these mixtures were extracted using water or ethanol, but simpler methods like tea infusions are gaining prominence. However, ensuring the efficacy and safety of phytomedicines demands high-quality plant material and stringent production processes. Advancements in biological screening techniques have shed light on the mechanisms of action of phytomedicines, emphasizing the significance of synergistic interactions among their constituents. Ten widely-used phytomedicines are outlined, detailing their applications, efficacy, and safety profiles, underscoring their global importance in healthcare. Moreover, ongoing research in phytomedicine development showcases the rich biodiversity's capacity to yield novel medicinal compounds. These studies highlight the potential of untapped plant sources in providing innovative solutions to medical challenges, offering promising avenues for future therapeutics. In essence, the utilization of phytomedicines underscores a fusion of traditional knowledge with modern scientific approaches, emphasizing both the importance of respecting ancient remedies and harnessing contemporary advancements for improved healthcare outcomes.

Synthetic Antimicrobial Peptides. V. Histidine-containing Antifungal Peptides with a “Linear” Type of Amphipathicity

A number of histidine-containing synthetic antifungal peptides with a “linear” type of amphipathicity (SAMP LTA) (F2Hx, H10F2, H10, where x = 7, 10, 13 and 16) have been synthesized and studied. Biological screening of such histidine-containing peptides for their antifungal and hemolytic activity was carried out. It has been shown that the presented histidine-containing SAMP LTAs are capable of effectively inhibiting the growth of opportunistic fungi Candida albicans and have low hemolytic activity in most cases not exceeding 10% even at their relatively high concentration of 400 μM in a medium containing erythrocytes. The antifungal activity of the studied peptides increases with increasing histidine residues in their composition, reaching the maximum value for the histidine-containing peptide F2H16 (MIC50 = 1.0 µM). It has been shown that as the chain length of peptides increases, their hemolytic toxicity also increases. In terms of therapeutic significance, the optimal peptides in the presented series of peptides were F2H10 and F2H13, which have higher selectivity than the short or longer peptides F2H7 or F2H16. The therapeutic index (TI) for these peptides was 233, 247, 79 and 60, respectively. It has been shown that histidine-containing derivatives of peptides with phenylalanine residues at the N-terminus of the peptide (F2H10) are less effective compared to similar peptides (H10F2) containing phenylalanine residues at the C-terminus. Among all the studied peptides, the most active was the H10 peptide (MIC50 = 0.7 µM), which does not contain phenylalanine residues, which in its antifungal activity is not only more effective than all other histidine-containing peptides, including the F2H16 peptide with 16 histidine residues, but also 4-5 times more effective than the antifungal peptide P113 (MIC50 = 3.4 µM), a short active fragment of natural histatin 5, well known in the literature. Due to its relatively low hemolytic and high antifungal activity, the presented histidine-containing SAMP LTAs have relatively high TI values, more than 60. Among all the studied peptides, peptides H10 and P113 have minimal, almost zero, hemolytic activity. However, due to its higher antifungal activity, the selectivity of peptide H10 (TI 1400) exceeds that of peptide P113 (TI 340) by more than 4 times. Thus, peptide H10, due to its high antifungal activity, low hemolytic toxicity and, accordingly, high therapeutic significance, can be used as a promising antifungal peptide drug.

Design, Development of Pyrazole-Linked Spirocyclopropyl Oxindole-Carboxamides as Potential Cytotoxic Agents and Type III Allosteric VEGFR-2 Inhibitors.

Tumor progression depends on angiogenesis, which is stimulated by growth factors like VEGF, targeting VEGFR kinase with small molecules is an effective anti-angiogenic therapeutic approach. The rational modification of sunitinib (VEGFR-2 inhibitor) to spirocyclopropyloxindoline carboxamides have been performed and their in vitro cytotoxic profiling was evaluated. The molecular modelling studies enabled the screening of designed analogues and identifying the possible interactions within the type III allosteric inhibitor binding site of VEGFR-2. The biological screening of synthesized compounds 15 a-y, revealed the ability of compound 15 w to inhibit the cell growth in MCF-7 cell line with IC50 value of 3.87±0.19 μM and alongside inhibition of VEGFR-2 kinase at a IC50 concentration of 4.34±0.13 μM was observed. Also, VEGFR-2 inhibition was validated through HUVEC tube formation inhibition assay. The qualitative assessment of apoptosis induction by 15 w in MCF-7 cells was evaluated through staining studies such as AO/EB and DAPI staining, whereas quantification of apoptosis and cell cycle analysis were performed through FACS analysis. The metastatic ability of the cancer cells was evaluated through inhibition of cell migration by a scratch wound healing assay. The current study strives to sequentially optimize the structural attributes of the 3-alkenyl oxindole core to surpass the existing challenges of well-known VEGFR-2 inhibitors. The findings observed from this study highlights that compound 15 w to be a prominent lead towards the development of clinical drug candidates.

Exploring Phytochemical profiling, Antioxidant, Enzyme Inhibition, and Antibacterial Potential of Callistemon viminalis (Sol. ex Gaertn.) G.Don ex Loudon)by In vitro and In silico Approaches.

Callistemon viminalis (Sol. ex Gaertn.) G. Don ex Loudon) (Family: Myrtaceae) is used for its medicinal properties in treating various metabolic disorders. We investigated the chemical characterization and biological screening of n-hexane extract of C. viminalis. Total phenolic content was (37.45 ± 7.40 mg GA.E/g D.E ± S.D) and total flavonoid content was (18.43 ± 6.34 mg R.E/g D.E ± S.D). The GC-MS screening of n-hexane extract tentatively identified 70 bioactive phytochemicals. The maximum antioxidant potential (289.99 ± 9.01 mg T.E/g D.E±S.D) was observed by FRAP assay. The enzyme inhibition assays revealed α-glucosidase and α-amylase inhibition (6.9 ± 0.13 and 7.2 ± 0.56 mmol of ACA.E/g D.E±S.D), urease (4.95 ± 0.9 mg of TU.E/g D.E±S.D), acetylcholinesterase (2.9 ± 0.08 mg GALA.E/g D.E±S.D), lipoxygenase (4.93 ± 1.05 mg of Indo.E/g D.E±S.D) and tyrosinase (4.33 ± 0.62 mg of KA.E/g D.E±S.D) inhibition. The extract showed antibacterial potential against Salmonella typhi (53.90±5.05)Bacillus subtilis (68.55±2.70%), Salmonella aureus (71.30±4.44%) and Pseudomonas aeruginosa (57.86±6.02%). The docking studies revealed a good docking interaction of ligands against the studied enzymes while ADME analysis revelaed pharmacokinetic profile of thephytoconstituents.C. viminalispossesses promising therapeutic potential and can be further explored for drug development and drug designing.

UPLC-HRMS/MS Guided Isolation and NMR Investigation of Major Flavonoids from Enarthrocarpus strangulatus Boissier (Brassicaceae) with In Vitro Enzymes Inhibitory Potential.

Various members of the family Brassicaceae are economically importantand traditionally used to treat many disorders. Among the family members, Enarthrocarpus strangulatusBoissier is a common Egyptian species that was rarely studied. Consequently, the current study aims to characterize its phytochemical composition and assess its potential bioactivity comprehensively. A metabolomics approach integrating UPLC-HRMS/MS-based molecular networking enabled the dereplication of 91 metabolites, including primary (i.e. organic acid, amino acids, fatty acids, and phospholipids) and secondary metabolites (i.e. glucosinolates, phenolic acids, and flavonoids). Among the 91 annotated features, 13 major metabolites were fully characterized following their isolation and purification. Exclusive of only three flavonoids, all the detected metabolites are described for the first time within this species. Furthermore, the crude extract and four major isolated flavonoids were subjected to in vitro biological screening, including antioxidant, radical scavenging, anti-diabetic, anti-Alzheimer's, and anti-inflammatory activities. It was noticed that nobiletin (61) exhibited the highest antioxidant and anti-Alzheimer's activities. At the same time, isorhamnetin 3-O-glucose (51) showed the highest anti-diabetic activity compared to the other isolated flavonoids and the total extract itself. Regarding the anti-inflammatory activity, no obvious differences were detected numerically among all studied flavonoids.

Two-Dimensional Layered Nano-MoS2 Induces Earthworm Immune Cell Apoptosis by Regulating Lysosomal Maintenance and Function: Toward Unbiased Screening and Validation of Suspicious Pathways.

Molybdenum-based nanosheets (NSMoS2) are increasingly applied in various fields and undergoing relevant risk evaluations on subjectively hypothesized toxicity pathways. However, risk assessment should be unbiased and focus on appropriate end points to avoid biased prescreening. Here, we developed an adverse biological outcome screening strategy based on nontargeted functional protein profiles in earthworm (Eisenia fetida) immune cells exposed to NSMoS2 and their ionic counterpart (Na2MoO4). Through this framework, the apoptosis-related processes with distinct mechanisms were rapidly identified and thoroughly validated phenotypically. Specifically, upon exposure to 50 μg Mo/mL Na2MoO4, cellular signaling and energy homeostasis were disrupted within the transcription-translation biological chain. The autophagic pathway was activated, which, together with energy deprivation, phenotypically induced significant autophagy that ultimately led to apoptosis. In contrast, NSMoS2, tested at the same concentration, caused a reprogramming of apoptotic gene and protein expressions. Transcriptome plasticity facilitated the endocytic-adaptive transcriptional profile characterized by cytoskeleton remodeling and lysosome organization/movement under NSMoS2 exposure. Subcellular dynamics further revealed NSMoS2-induced lysosomal damage with a time-sensitive physiological window, ultimately mediating apoptosis. These findings provide a mechanistic and visual understanding of the distinct risk profile of NSMoS2 compared to molybdate, highlighting the importance of integrating nontargeted screening and phenotypic validation in early risk warning.

Self-Powered FEN1 Biosensor Based on Accelerated CRISPR/Cas Trans-Cleavage around Porous Fe3O4 Nanoparticles.

Flap endonuclease 1 (FEN1) is a structure-specific endonuclease that plays a critical role in the maintenance of genome integrity. In this work, we demonstrate a novel self-powered electrochemical FEN1 biosensor for potential applications in molecular diagnosis. Porous Fe3O4 nanoparticles are first prepared, and single-strand DNA probes are absorbed on the surface of the nanoparticles. Thus, electrochemical species of [Fe(CN)6]3- can be encapsulated inside the porous nanoparticles with the molecular gate of negatively charged DNA. On the other hand, a dumbbell structured DNA probe with 5' flap is designed. FEN1 is able to cleave the flap and activate the CRISPR/Cas system for the digestion of single-stranded DNA around Fe3O4 nanoparticles. As a result, the leakage of [Fe(CN)6]3- contributes to an enhanced electrochemical response, which can be used to reveal the level of FEN1. The high sensitivity of this biosensor is due to the application of porous nanomaterials and Mn2+ accelerated CRISPR/Cas cleavage. It succeeds in detection of biological samples and screening of FEN1 inhibitors. Therefore, this proposed method has potential applications in the early diagnosis of diseases and drug discovery.

Antioxidant and Antibacterial Screening and Hg(II) Sensing, Activities of Cu(II)pyridine-2,6-dicarboxylate Complexes.

In this study five different complexes of Cu(II) were synthesized for the purpose of environmentally notorious mercury sensing and preliminary biological screening. Pyridine-2,6-dicarboxylic acid (also known as dipicolinic acid, and abbreviated as H2DPA), 3-phenyl pyrazole (3-ppz), 4-iodo-1H-pyrazole (4-ipz), 4-nitropyrazole (4-npz), 4-bromopyrazole (4-bpz), and 4-chloropyrazole (4-cpz) were chosen as potential ligands. The synthesized complexes labelled as 1-5, namely [Cu(DPA)(3-ppz)], [Cu(DPA)(4-ipz)], [Cu(DPA)(4-npz)], [Cu(DPA)(4-bpz)], [Cu(DPA)(4-cpz)], were proposed based on spectroscopic data (FTIR, TGA, and UV-visible spectroscopy). These complexes feature C=O functionalities that are not involved in coordination and may be used for further applications. The isolated complexes were utilized for detecting Hg(II) ions in water samples. Various concentrations of Hg(II) ions were prepared for detection purposes, and changes in absorption concerning complexes 1-5 were determined using UV-Visible spectroscopy. It was found that complexes 3 and 4 exhibit efficient sensing abilities towards Hg(II) ions. The antibacterial activities of complexes 1-5 were assessed against S. typhi and E. coli. The complexes 1 and 3 displayed good antibacterial activities against S. typhi (13.67, and 13.56 mm, respectively) while complexes 1, 2 and 4 were found to be efficient against E. coli (11.6, 12.66, 11.31 mm, respectively). The absorption maxima of 2,2-diphenyl-1-picryhydrazyl (DPPH) at 517 nm, considerably shifted upon addition of complexes 1-5. The results reveal that the complexes possess potential free radical scavenging abilities.

Microwave-Assisted Synthesis of Pyridine-Conjugated 2-Methyl-6-(4-nitrophenyl)nicotine Hydrazide Schiff Base: Biological Screening of In Vitro Antimicrobial and In Silico ADMET Investigation

Microwave-Assisted Synthesis of Pyridine-Conjugated 2-Methyl-6-(4-nitrophenyl)nicotine Hydrazide Schiff Base: Biological Screening of In Vitro Antimicrobial and In Silico ADMET Investigation

Xeniaphyllane and Xeniolide Diterpenes from the Deep-Sea Soft Coral Paragorgia arborea.

As exploration of ocean depths >1000 m is only possible by expensive remotely operated underwater vehicles, deep-sea invertebrates represent a largely untapped source of marine metabolites for potential applications in medicine. Our current study aims to investigate these deep-sea invertebrates in Ireland to discover new biological and chemical diversity. Here, we investigate the bubble gum coral, Paragorgia arborea, collected at 1500 m depth from Whittard canyon in the Northeastern Atlantic. This species was selected following chemical profiling and biological screening. The isolation and structure elucidation of the main metabolites yielded three new diterpenes, namely, miolenol (1) and epoxymiolenol (2) characterized by the rare bicyclo[7.2.0]undec-4-ene skeleton, and the xeniolide epoxycoraxeniolide A (3), together with five known diterpenes. The structures of the new compounds were identified through extensive NMR analysis with their absolute configurations assigned by comparison between experimental and TDDFT-calculated ECD. The eight compounds were screened for cytotoxicity and antimalarial activity, and none displayed noteworthy bioactivity.

Characterization of Bimetallic (Zinc and Gold) Nanoparticles of Cryptostegia grandiflora Plant Extract and Their Biological Screening .

The goal of this learning was to explore the uses of Cryptostegia grandiflora plant extract in the green formulation of bimetallic zinc-gold nanoparticles along with pharmacological evaluation. Green synthesis and other techniques are more advantageous than chemical and physical procedures because they produce nanoparticles in an environmentally responsible and economically viable manner. An ethanolic extract of C. grandiflora was obtained through the use of Soxhlet extraction. Additionally, an ethanolic extract of C. grandiflora and components from the extract were identified using GC-MS research after mixing plant extract (C. grandiflora) with zinc acetate and chloroauric acid solutions and letting it sit for a while. UV-visible spectroscopy was employed to analyze the formation of nanoparticles, while FTIR was used for their characterization.

Miniaturized Modular Click Chemistry-enabled Rapid Discovery of Unique SARS-CoV-2 Mpro Inhibitors With Robust Potency and Drug-like Profile.

The COVID-19 pandemic has required an expeditious advancement of innovative antiviral drugs. In this study, focused compound libraries are synthesized in 96- well plates utilizing modular click chemistry to rapidly discover potent inhibitors targeting the main protease (Mpro) of SARS-CoV-2. Subsequent direct biological screening identifies novel 1,2,3-triazole derivatives as robust Mpro inhibitors with high anti-SARS-CoV-2 activity. Notably, C5N17B demonstrates sub-micromolar Mpro inhibitory potency (IC50 = 0.12 µM) and excellent antiviral activity in Calu-3 cells determined in an immunofluorescence-based antiviral assay (EC50 = 0.078 µM, no cytotoxicity: CC50 > 100 µM). C5N17B shows superior potency to nirmatrelvir (EC50 = 1.95 µM) and similar efficacy to ensitrelvir (EC50 = 0.11 µM). Importantly, this compound displays high antiviral activities against several SARS-CoV-2 variants (Gamma, Delta, and Omicron, EC50 = 0.13 - 0.26 µM) and HCoV-OC43, indicating its broad-spectrum antiviral activity. It is worthy that C5N17B retains antiviral activity against nirmatrelvir-resistant strains with T21I/E166V and L50F/E166V mutations in Mpro (EC50 = 0.26 and 0.15 µM, respectively). Furthermore, C5N17B displays favorable pharmacokinetic properties. Crystallography studies reveal a unique, non-covalent multi-site binding mode. In conclusion, these findings substantiate the potential of C5N17B as an up-and-coming drug candidate targeting SARS-CoV-2 Mpro for clinical therapy.

Synthesis, molecular modelling, and biological evaluation of novel quinoxaline derivatives for treating type II diabetes

Quinoxalines are benzopyrazine derivatives with significant therapeutic impact in the pharmaceutical industry. They proved to be useful against inflammation, bacterial, fungal, viral infection, diabetes and other applications. Very recently, in January 2024, the FDA approved new quinoxaline containing drug, erdafitinib for treatment of certain carcinomas. Despite the diverse biological activities exhibited by quinoxaline derivatives and the role of secretory phospholipase A2 (sPLA2) in diabetes-related complications, the potential of sPLA2-targeting quinoxaline-based inhibitors to effectively address these complications remains unexplored. Therefore, we designed novel sPLA2- and α-glucosidase-targeting quinoxaline-based heterocyclic inhibitors to regulate elevated post-prandial blood glucose linked to patients with diabetes-related cardiovascular complications. Compounds 5a–d and 6a–d were synthesised by condensing quinoxaline hydrazides with various aryl sulphonyl chlorides. Biological screening revealed compound 6a as a potent sPLA2 inhibitor (IC50 = 0.0475 µM), whereas compound 6c most effectively inhibited α-glucosidase (IC50 = 0.0953 µM), outperforming the positive control acarbose. Moreover, compound 6a was the best inhibitor for both enzymes. Molecular docking revealed pharmacophoric features, highlighting the importance of a sulfonohydrazide moiety in the structural design of these compounds, leading to the development of potent sPLA2 and α-glucosidase inhibitors. Collectively, our findings helped identify promising candidates for developing novel therapeutic agents for treating diabetes mellitus.

Pyrazole-based N-phenyl pyrazolines: Synthesis, docking, and pharmacological evaluation

A series of methoxy substituted pyrazole based pyrazoline derivatives (4a-j) were synthesized in good to excellent yield from corresponding pyrazole-chalcones (3a-j). All synthesized derivatives were characterized and screened for their in vitro anti-inflammatory, antioxidant, antidiabetic, and antibacterial activities. Among the series, compounds 4f, 4j, 4a, and 4i showed better anti-inflammatory activity as compared to diclofenac sodium. In DPPH free radical scavenging assay, all the compounds were shown excellent activity and moderate to good activity in SO and NO free radical scavenging assay as compared to standard ascorbic acid. Antibacterial screening of synthesized pyrazolines showed that compounds 4f and 4j have significant antibacterial activity. The compounds 4j, 4f, 4h, 4a, and 4c have shown comparable inhibition of alpha-amylase enzyme leading to good antidiabetic activity as compared to standard acarbose. Molecular docking studies suggest that these compounds have strong binding with COX-2 and alpha-amylase enzyme due to significant capability of aromatic and hydrophobic interaction. The outstanding results of reported compounds in all biological screening will pave the way for the design of new drug candidate bearing pyrazole moiety.

Protein phosphatase PP2Cα S-glutathionylation regulates cell migration

Redox signaling is a fundamental mechanism that controls all major biological processes partly via protein cysteine oxidations, including S-glutathionylation. Despite over 2,000 cysteines identified to form S-glutathionylation in databases, the identification of redox cysteines functionally linked to a biological process of interest remains challenging. Here, we demonstrate a strategy combining glutathionylation proteomic database, bioinformatics, and biological screening, which resulted in the identification of S-glutathionylated proteins, including PP2Cα, as redox players of cell migration. We showed that PP2Cα, a prototypical magnesium-dependent serine/threonine phosphatase, is susceptible to S-glutathionylation selectively at non-conserved C314. PP2Cα glutathionylation causes increased migration and invasion of breast cancer cell lines in oxidative stress or upon hydrogen peroxide production. Mechanistically, PP2Cα glutathionylation modulates its protein-protein interactions, activating c-Jun N-terminal kinase (JNK) and extracellular signal-regulated kinase (ERK) pathways to elevate migration and invasion. In addition, PP2Cα glutathionylation occurs in response to epidermal-growth factor, supporting a serine/threonine phosphatase PP2Cα as a new redox player in growth factor signal transduction.

Comparison of In Vitro and In Vivo Biological Screening of Nano‐Palladium (II) and Platinum (II)‐Based Compounds With DFT and Molecular Docking Study

ABSTRACTWithin the current challenges in medicinal chemistry, the creation of novel and improved therapeutic agents stands out. 2‐Cyano‐3‐(thiophen‐2‐yl)prop‐2‐enethioamide (CTPTA) ligand was complexed with palladium (II) and platinum (II) ions within the nanoscale with the molecular formula [M (CTPTA)Cl2]. H2O. The CTPTA ligand and its complexes were characterized by elemental analysis, UV–Vis spectra, FTIR, mass spectra, TGA, magnetic measurement, and the molar conductance technique. Analysis with a scanning electron microscope (SEM) revealed that the nanostructure dimension of both complexes is predominantly between 10 and 30 nm. The CTPTA ligand functions as a bidentate ligand, utilizing thione sulfur, and cyanide nitrogen atoms. Density functional theory was employed to analyze the geometric structure properties of the CTPTA ligand and its complexes. Natural population (NPA) and Mulliken population (MPA) methods were used to calculate the charge distribution. The cytotoxic impact results of all compounds on human liver cancer (HepG2) cell line were satisfactory. The ligand and its complexes were also tested against gram‐negative and gram‐positive bacteria in vitro. The findings of the molecular docking study supported the cytotoxicity and antibacterial effects. The antioxidant and anti‐inflammation activities of synthesized palladium (II) and platinum (II) complexes had a great spectrum of activity. The preclinical pharmacokinetic studies on albino rats revealed that the newly studied complexes achieved excellent antitumor results. This was clear in the investigated parameters, especially the amelioration of AFP levels, liver weight, oxidative stress, and lobular hepatic architecture injury.

Michael addition of ethyl acetoacetate on dibenzylideneacetone derivatives: Synthesis, spectroscopy, antimicrobial and in silico studies

A series of trisubstituted cyclohexenones incorporating a styryl framework were synthesized by Michael addition reaction of ethyl acetoacetate onto dibenzylideneacetone derivatives. The reaction was carried out in ethanol in the presence of piperidine as a basic catalyst. The cyclocondensation starts with a 1,4-Michael addition of ethyl acetoacetate on only one ethylenic bond of the Michael acceptors, followed by an intramolecular cyclization of the Michael adduct to form the corresponding cyclohexenones. The structures of the synthesized products were established based on the IR, (1H & 13C) NMR, and HRMS spectral data. The in vitro evaluation of the antimicrobial effect of the synthesized compounds was tested against B. subtilis, S. aureus, C. albicans, and P. mirabilis strains. In silico studies, including molecular docking, ADMET predictions, and molecular dynamics simulations, were additionally performed to correlate observed and computed outcomes of the biological screening, providing further insights into the compounds' potential efficacy.

Synthesis of the Corrected Structure Assigned to Clonorosin B, an Alkaloid Obtained from the Soil-derived Fungus Clonostachys rosea YRS-06.

The revised structure, 2, assigned to the title natural product has been prepared by chemical synthesis using a reaction sequence involving six simple steps starting from 2,3-dimethoxybenzaldehyde and proceeding via intermediates 8, 12, and 14. A comparison of the NMR data acquired on synthetically derived compound 2 with those reported for the natural product reveals an excellent match. Preliminary biological screening of compound 2 along with analogues/precursors 7, 9, 10, 11, 13, 14, and 15 revealed that none exhibited antibacterial, antifungal or cytotoxic effects.

Enabling Modular Click Chemistry Library through Sequential Ligations of Carboxylic Acids and Amines.

High-throughput synthesis and screening of chemical libraries play pivotal roles in drug discovery. Click chemistry has emerged as a powerful strategy for constructing highly modular chemical libraries. However, the development of new click reactions and unlocking new clickable building blocks remain exceedingly challenging. Herein, we describe a double-click strategy that enables the sequential ligations of widely available carboxylic acids and amines with fluorosulfuryl isocyanate (FSO2NCO) via a modular amidation/SuFEx (sulfur-fluoride exchange) process. This method provides facile access to chemical libraries of N-fluorosulfonyl amides (RCONHSO2F) and N-acylsulfamides (RCONHSO2NR'R'') in near-quantitative yields under simple and practical conditions. The robustness and efficiency of this double click strategy is showcased by the facile construction of chemical libraries in 96-well microtiter plates from a large number of carboxylic acids and amines. Preliminary biological activity screening reveals that some compounds exhibit high antimicrobial activities against Gram-positive bacterium S. aureus and drug-resistant MRSA (MIC up to 6.25 μg ⋅ mL-1). These results provide compelling evidence for the potential application of modular click chemistry library as an enabling technology in high-throughput medicinal chemistry.