Magnetic stir bars are routinely used by every chemist doing synthetic or catalytic transformations in solution. Each bar lasts for months or years, as the regular PTFE (polytetrafluoroethylene) coating is believed to be highly durable, inert, and resistant to multiple washings and cleanings. By using electron microscopy, we found out quite unexpectedly that the surface of magnetic stir bars is susceptible to microscale destruction and forms various types of defects. These microscopic defects effectively trap and accumulate trace amounts of active components from reaction mixtures, most notably metal species. Trapped in surface defects, the impurities escape elimination by washing and cleaning, thus remaining on the surface. FE-SEM/EDX analysis shows that the surface of used stir bars is littered with contaminants representing a variety of metals (Pd, Pt, Au, Fe, Co, Cr, etc.). ESI-MS monitoring corroborates the transfer of the trace metal species to reaction mixtures, while chemical tests indicate their significant catalytic activity. A theoretical DFT study reveals a remarkably high binding energy of metal atoms to the PTFE surface, especially in cases of local mechanical disruption or chemical influence. A plausible mechanism of PTFE surface contamination is suggested, and the results show that metal contamination of reusable polymercoated labware is greatly underestimated. The present study suggests that corresponding control experiments with an unused stir bar (to avoid misinterpretations due to the influence of contamination of magnetic stir bars) are a "must do" for reporting high-performance catalytic reactions, reactions with low catalyst loadings, metal-catalyst-free reactions, and mechanistic studies.
The mercury test is a rapid and widely used method for distinguishing truly homogeneous molecular catalysis from nanoparticle metal catalysis. In the current work, using various M 0 and M II complexes of palladium and platinum that are often used in homogeneous catalysis as examples, we demonstrated that the mercury test is generally inadequate as a method for distinguishing between homogeneous and cluster/nanoparticle catalysis mechanisms for the following reasons: (i) the general and facile reactivity of both molecular M 0 and M II complexes toward metallic mercury and (ii) the very high and often unpredictable dependence of the test results on the operational conditions and the inability to develop universal quantitatively defined operational parameters. Two main types or mercury-induced transformations, the cleavage of M 0 complexes and the oxidative−reductive transmetalation of M II complexes, including a reaction of highly popular M II /NHC complexes, were elucidated using NMR, ESI-MS, and EDXRF techniques. A mechanistic picture of the reactions involving metal complexes was revealed with mercury, and representative metal species were isolated and characterized. Even in an attempt to not overstate the results, one must note that the use of the mercury tests often leads to inaccurate conclusions and complicates the mechanistic studies of these catalytic systems. As a general concept, distinguishing reaction mechanisms (homogeneous vs cluster/nanoparticle) by using catalyst poisoning requires careful rethinking in the case of dynamic catalytic systems.
Profiling
the heterogeneous landscape of cell types and biomolecules
is rapidly being adopted to address current imperative research questions.
Precision medicine seeks advancements in molecular spatial profiling
techniques with highly multiplexed imaging capabilities and subcellular
resolution, which remains an extremely complex task. Surface-enhanced
Raman spectroscopy (SERS) imaging offers promise through the utilization
of nanoparticle-based contrast agents that exhibit narrow spectral
features and molecular specificity. The current renaissance of gold
nanoparticle technology makes Raman scattering intensities competitive
with traditional fluorescence methods while offering the added benefit
of unsurpassed multiplexing capabilities. Here, we present an expanded
library of individually distinct SERS nanoparticles to arm researchers
and clinicians. Our nanoparticles consist of a ∼60 nm gold
core, a Raman reporter molecule, and a final inert silica coating.
Using density functional theory, we have selected Raman reporters
that meet the key criterion of high spectral uniqueness to facilitate
unmixing of up to 26 components in a single imaging pixel in vitro and in vivo. We also demonstrated
the utility of our SERS nanoparticles for targeting cultured cells
and profiling cancerous human tissue sections for highly multiplexed
optical imaging. This study showcases the far-reaching capabilities
of SERS-based Raman imaging in molecular profiling to improve personalized
medicine and overcome the major challenges of functional and structural
diversity in proteomic imaging.
The great impact of the nanoscale organization of reactive species on their performance in chemical transformations creates the possibility of fine-tuning of reaction parameters by modulating the nano-level properties. This methodology is extensively applied for the catalysts development whereas nanostructured reactants represent the practically unexplored area. Here we report the palladium- and copper-catalyzed cross-coupling reaction involving nano-structured nickel thiolate particles as reagents. On the basis of experimental findings we propose the cooperative effect of nano-level and molecular-level properties on their reactivity. The high degree of ordering, small particles size, and electron donating properties of the substituents favor the product formation. Reactant particles evolution in the reaction is visualized directly by dynamic liquid-phase electron microscopy including recording of video movies. Mechanism of the reaction in liquid phase is established using on-line mass spectrometry measurements. Together the findings provide new opportunities for organic chemical transformations design and for mechanistic studies.
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