Dynamic light scattering studies of the effects of salts on the diffusivity of cationic and anionic cavitands

Wishard, Anthony; Gibb, Bruce C.

doi:10.3762/bjoc.14.195

Cited by 9 publications

(9 citation statements)

References 31 publications

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“…This free energy difference corresponds to a p K a shift between the capsules of 3.0, which again is in reasonable agreement with those reported (Figure ). Overall, these agreements are excellent given the inherent assumptions made in this simple model, not the least of which is the neglect of ion-specific binding to the outside of the two capsules. , Furthermore, the model confirms–at least for the two host discussed here–the primary role of Coulombic forces in promoting cyclizations within the capsules. That stated, a potential cautionary note here is that the modeling does not reveal any significant difference in the internal EP field that may explain the differences in stabilization of the thiolate and TS.…”

Section: Resultssupporting

confidence: 58%

Electrostatic Control of Macrocyclization Reactions within Nanospaces

et al. 2019

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The intrinsic structural complexity of proteins makes it hard to identify the contributions of each noncovalent interaction behind the remarkable rate accelerations of enzymes. Coulombic forces are evidently primary, but despite developments in artificial nanoreactor design, a picture of the extent to which these can contribute has not been forthcoming. Here we report on two supramolecular capsules that possess structurally identical inner-spaces that differ in the electrostatic potential (EP) field that envelops them: one positive and one negative. This architecture means that only changes in the EP field influence the chemical properties of encapsulated species. We quantify these influences via acidity and rates of cyclization measurements for encapsulated guests, and we confirm the primary role of Coulombic forces with a simple mathematical model approximating the capsules as Born spheres within a continuum dielectric. These results reveal the reaction rate accelerations possible under Coulombic control and highlight important design criteria for nanoreactors.

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Section: Resultssupporting

confidence: 58%

Electrostatic Control of Macrocyclization Reactions within Nanospaces

et al. 2019

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“…Regarding ion association, we have previously demonstrated both specific ion binding to the crown of four ammonium groups defined by the pendent groups in 1 , 60 as well as nonspecific association (ion condensation) to the host and its dimer capsule. 41 , 61 In contrast, there are no specific cation binding sites in 2 or its capsule; only weak ion condensation has been observed. 41 , 62 Irrespective of the type of binding, increases in the ionic strength and/or swapping the capsule counterions by the addition of ions with higher cavitand affinity lead to a reduction in its EPF.…”

Section: Resultsmentioning

confidence: 96%

“…The effective charge of the two host capsules is less than their formal ±16 because of attenuation from associating counterions, and charge transfer to the solvation shell waters. Regarding ion association, we have previously demonstrated both specific ion binding to the crown of four ammonium groups defined by the pendent groups in 1 , as well as nonspecific association (ion condensation) to the host and its dimer capsule. , In contrast, there are no specific cation binding sites in 2 or its capsule; only weak ion condensation has been observed. , Irrespective of the type of binding, increases in the ionic strength and/or swapping the capsule counterions by the addition of ions with higher cavitand affinity lead to a reduction in its EPF. In the case of the capsules, this can induce a change in the nature of an assembly or modulate the chemical reactivity of an internalized guest …”

Section: Resultsmentioning

confidence: 99%

“…To gain more insight into the mechanism of the cyclization of 3 within the capsules, we investigated the effects on the nature of exogenous salts upon reaction rates within the two hosts (SI, Section 5). To minimize pairing between the ions of the added salt, we selected highly solvated sodium and chloride counterions for, respectively, studying how anions and cations affect cyclization rates within 1 2 and within 2 2 . , In all cases, the rate constants for cyclization were measured in the presence of 10 mM added salt and compared to the rate of the reaction with only base (NaOD) present. In most cases, 1 H NMR spectroscopy revealed that the added salt had no direct effect on the bound guest.…”

Section: Resultsmentioning

confidence: 99%

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Electrostatic Potential Field Effects on Amine Macrocyclizations within Yoctoliter Spaces: Supramolecular Electron Withdrawing/Donating Groups

et al. 2021

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The central role of Coulombic interactions in enzyme catalysis has inspired multiple approaches to sculpting electrostatic potential fields (EPFs) for controlling chemical reactivity, including ion gradients in water microdroplets, the tips of STMs, and precisely engineered crystals. These are powerful tools because EPFs can affect all reactions, even those whose mechanisms do not involve formal charges. For some time now, supramolecular chemists have become increasingly proficient in using encapsulation to control stoichiometric and catalytic reactions. However, the field has not taken advantage of the broad range of nanocontainers available to systematically explore how EPFs can affect reactions within their inner-spaces. With that idea in mind, previously, we reported on how positively and negatively charged supramolecular capsules can modulate the acidity and reactivity of thiol guests bound within their inner, yoctoliter spaces (Cai, X.; Kataria, R.; Gibb, B. C. J. Am. Chem. Soc . 2020 , 142 , 8291–8298; Wang, K.; Cai, X.; Yao, W.; Tang, D.; Kataria, R.; Ashbaugh, H. S.; Byers, L. D.; Gibb, B. C. J. Am. Chem. Soc. 2019 , 141 , 6740–6747). Building on this, we report here on the cyclization of 14-bromotetradecan-1-amine inside these yoctoliter containers. We examine the rate and activation thermodynamics of cyclization (Eyring analysis), both in the absence and presence of exogenous salts whose complementary ion can bind to the outside of the capsule and hence attenuate its EPF. We find the cyclization rates and activation thermodynamics in the two capsules to be similar, but that for either capsule attenuation of the EPF slows the reaction down considerably. We conclude the capsules behave in a manner akin to covalently attached electron donating/withdrawing groups in a substrate, with each capsule enforcing their own deviations from the idealized S N 2 mechanism by moving electron density and charge in the activated complex and TS, and that the idealized S N 2 mechanism inside the theoretical neutral host is relatively difficult because of the lack of solvation of the TS.

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“…Dynamic light scattering (DLS), NMR spectroscopy, and dark-field microscope are very useful tools for studying the Hofmeister effect. [12,13,16,[28][29][30] DLS technique mainly depends on the Brownian motion of particles. It can provide quite quantita-tive information such as hydrodynamic diameters for studying the Hofmeister effect.…”

Section: Introductionmentioning

confidence: 99%

Nanopore Sensing Technique for Studying the Hofmeister Effect

Wei

Chen

Wang

2022

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The nanopore sensing technique is an emerging method of detecting single molecules, and extensive research has gone into various fields, including nanopore sequencing and other applications of single‐molecule studies. Recently, several researchers have explored the specific ion effects in nanopore channels, enabling a unique understanding of the Hofmeister effect at the single‐molecule level. Herein, the recent advances of using nanopore sensing techniques are reviewed to study the Hofmeister effect and the physicochemical mechanism of this process is attempted. The challenges and goals are also discussed for the future in this field.

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Dynamic light scattering studies of the effects of salts on the diffusivity of cationic and anionic cavitands

Cited by 9 publications

References 31 publications

Electrostatic Control of Macrocyclization Reactions within Nanospaces

Electrostatic Control of Macrocyclization Reactions within Nanospaces

Electrostatic Potential Field Effects on Amine Macrocyclizations within Yoctoliter Spaces: Supramolecular Electron Withdrawing/Donating Groups

Nanopore Sensing Technique for Studying the Hofmeister Effect

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