Phosphorus-Element Bond-Forming Reactions

White phosphorus (P4) has been the traditional entry point into phosphorus chemistry. The thirteenth element to have been isolated, it can be oxidized with elemental oxygen or chlorine, or reduced in a variety of ways. We investigated its reduction using early transition metal systems and breakdown to produce complexes with terminal metal-phosphorus triple bonds. Such terminal phosphide complexes possess nucleophilic phosphorus atoms, paving the way to new phosphorus-element bonded systems.

Folding- and dynamics-based electrochemical biosensors

This seminar will cover the recent advances in the design and fabrication of folding- and dynamics-based electrochemical biosensors. These devices, which are often termed electrochemical DNA (E-DNA), aptamer-based (E-AB), and peptide-based (E-PB) sensors, are fabricated via direct immobilization of a thiolated and methylene blue (MB)-modified oligonucleotide or peptide probe onto a gold electrode. Binding of an analyte to the probe changes its structure and/or flexibility, which, in turn, influences the electron transfer between the MB label and the interrogating electrode.

In silico searches for (in)efficient electrocatalysts through chemical and material compound space

This talk will provide an overview of our group’s work using both standard and atypical high-performance computational chemistry modeling to elucidate atomic scale reaction mechanisms of catalytic reactions. I will introduce our toolkit of in silico methods for accurately modeling (electro)catalytic reactions in solvating environments. I will then present how in silico methods can be used for predictive insights into chemical and material design.

Interactions of antimicrobial and cell-penetrating peptides with lipid membranes

Antimicrobial, cytolytic, and cell-penetrating peptides, often called membrane-active peptides, belong to a variety of structural classes, including, alpha-helical, beta-sheet, unstructured, and cyclic polypeptides, among others. Those peptides were intensely studied in the 1990s and early 2000s with the hope of opening the door for urgently needed new antibiotics. For about 15 years we have studied the kinetics and thermodynamics of their interactions with lipid vesicles with the hope of understanding the mechanism of their function.

Quantifying biochemistry in living cells

Increasingly, fluorescent tools are providing insight into the “dark matter” of the cellular milieu: small molecules, secondary metabolites, metals, and ions.  One of the great promises of such tools is the ability to quantify cellular signals in precise locations with high temporal resolution.  Yet this is coupled with the challenge of how to ensure that our tools are not perturbing the underlying biology and the need to systematically measure hundreds of individual cells over time.


Subscribe to RSS - Spring