| Targeted protein degradation: elements of PROTAC design |
65 |
| Fundamentals of ion mobility spectrometry |
39 |
| Getting to know the neighborhood: using proximity-dependent biotinylation to characterize protein complexes and map organelles |
38 |
| Anticancer metal-N-heterocyclic carbene complexes of gold, platinum and palladium |
33 |
| Inhibitors of protein-protein interactions (PPIs): an analysis of scaffold choices and buried surface area |
33 |
| Collision induced unfolding of isolated proteins in the gas phase: past, present, and future |
28 |
| The roles of microRNAs in epigenetic regulation |
27 |
| Carboxylic acid reductase enzymes (CARs) |
26 |
| Transaminases for chiral amine synthesis |
26 |
| Synthesis of chiral amines using redox biocatalysis |
25 |
| Chemical cross-linking with mass spectrometry: a tool for systems structural biology |
24 |
| Peptide nucleic acid (PNA) and its applications in chemical biology, diagnostics, and therapeutics |
24 |
| Natural product derived privileged scaffolds in drug discovery |
24 |
| The application of ion-mobility mass spectrometry for structure/function investigation of protein complexes |
24 |
| Trending topics and open questions in anaerobic ammonium oxidation |
23 |
| Selective C-H bond functionalization with engineered heme proteins: new tools to generate complexity |
23 |
| Protein identification strategies in MALDI imaging mass spectrometry: a brief review |
22 |
| Insights into the physiology of ammonia-oxidizing microorganisms |
22 |
| The potential of ion mobility-mass spectrometry for non-targeted metabolomics |
21 |
| Recent advances in DNA nanotechnology |
21 |
| Reactive sulfur species (RSS): persulfides, polysulfides, potential, and problems |
20 |
| Biocatalytic reduction of activated C=C-bonds and beyond: emerging trends |
19 |
| Bifunctional chemical probes inducing protein-protein interactions |
19 |
| Reactive-cysteine profiling for drug discovery |
19 |
| Will morphing boron-based inhibitors beat the beta-lactamases? |
19 |
| Recent preparative applications of redox enzymes |
18 |
| 'Democratized' genomic enzymology web tools for functional assignment |
18 |
| Recent developments in the application of P450 based biocatalysts |
18 |
| The potential of Ion Mobility Mass Spectrometry for high-throughput and high-resolution lipidomics |
17 |
| Next-generation genetic code expansion |
17 |
| Metal complexes promoting catalytic cleavage of nucleic acids - biochemical tools and therapeutics |
17 |
| Activity-based sensing fluorescent probes for iron in biological systems |
17 |
| Advances in mass spectrometry imaging coupled to ion mobility spectrometry for enhanced imaging of biological tissues |
17 |
| Shedding light on biocatalysis: photoelectrochemical platforms for solar-driven biotransformation |
17 |
| An overview of activity-based probes for glycosidases |
16 |
| Advances in gadolinium-based MRI contrast agent designs for monitoring biological processes in vivo |
16 |
| The application of ion mobility mass spectrometry to metabolomics |
16 |
| Recent advances in the optical control of protein function through genetic code expansion |
16 |
| Targeted protein degradation and the enzymology of degraders |
15 |
| Whole-cell based synthetic enzyme cascades-light and shadow of a promising technology |
15 |
| New players in phototherapy: photopharmacology and bio-integrated optoelectronics |
15 |
| A bright future: optogenetics to dissect the spatiotemporal control of cell behavior |
15 |
| DNA methylation as a genomic marker of exposure to chemical and environmental agents |
14 |
| Image scanning microscopy |
14 |
| Aptamer-based and aptazyme-based riboswitches in mammalian cells |
14 |
| Recent progress in photoacoustic molecular imaging |
14 |
| Synthesis of modified proteins dehydroalanine |
14 |
| Creation of unnatural base pairs for genetic alphabet expansion toward synthetic xenobiology |
14 |
| Advancing the large-scale CCS database for metabolomics and lipidomics at the machine-learning era |
13 |
| Probing microscopic conformational dynamics in folding reactions by measuring transition paths |
13 |
