Michael T. Rerick scite author profile

There are many processes that actively alter the concentrations of solutes in the extracellular space. Enzymatic reactions, either by soluble enzymes or membrane-bound ectoenzymes, and uptake or clearance are two such processes. Investigations of ectoenzymatic reactions in vivo is challenging, particularly in the brain. Studies using microdialysis have revealed some qualitative information about what enzymes may be present, but microdialysis is a sampling technique so it is not designed to control conditions such as a substrate concentration outside the probe. Micropush–pull perfusion has been used to determine which nitric oxide synthase enzymes are active in discrete regions of the rat retina. Ectopeptidases are a particularly important class of ectoenzymes. As far as it is known, the extracellular activity of active peptides in the brain is controlled by ectopeptidases. To understand ectopeptidase activity, we developed a physical probe and an accompanying method. The probe has a two-channel source that supplies substrate or substrate plus inhibitor using electroosmotic perfusion (EOP). It also has a microdialysis probe to collect products and unreacted substrate. The method provides quantitative estimates of substrate-to-product conversion and the influence of inhibitors on this process. The quantitative estimates are made possible by including a d-amino acid-containing peptide analog of the substrate in the substrate-containing solution infused. Quantitative analysis of substrate, substrate analog, and products is carried out by quantitative, online capillary liquid chromatography-tandem mass spectrometry. The electroosmotic perfusion-microdialysis probe and associated method were used to determine the effect of the selective inhibitor HFI-419 on insulin-regulated aminopeptidase (EC 3.4.11.3) in the rat neocortex.

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Validation of Dexamethasone-Enhanced Continuous-Online Microdialysis for Monitoring Glucose for 10 Days after Brain Injury

Gifford

Robbins

Jaquins-Gerstl

et al. 2021

ACS Chem. Neurosci.

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Traumatic brain injury (TBI) induces a pathophysiologic state that can be worsened by secondary injury. Monitoring brain metabolism with intracranial microdialysis can provide clinical insights to limit secondary injury in the days following TBI. Recent enhancements to microdialysis include the implementation of continuously operating electrochemical biosensors for monitoring the dialysate sample stream in real time and dexamethasone retrodialysis to mitigate the tissue response to probe insertion. Dexamethasone-enhanced continuous-online microdialysis (Dex-enhanced coMD) records long-lasting declines of glucose after controlled cortical impact in rats and TBI in patients. The present study employed retrodialysis and fluorescence microscopy to investigate the mechanism responsible for the decline of dialysate glucose after injury of the rat cortex. Findings confirm the long-term functionality of Dex-enhanced coMD for monitoring brain glucose after injury, demonstrate that intracranial glucose microdialysis is coupled to glucose utilization in the tissues surrounding the probes, and validate the conclusion that aberrant glucose utilization drives the postinjury glucose decline.

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Multiplicative On-Column Solute Focusing Using Spatially Dependent Temperature Programming for Capillary HPLC

2019

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The benefits of capillary liquid chromatography columns are truly realized when small, limited sample volumes require signal enhancement, but the available sample volume does not permit on-column focusing during injection onto a larger column. This dilemma is common when samples are naturally small or precious (such as in biological, forensic, art, and archeological investigations) and analyte concentrations are low. Signal enhancement by solvent-based focusing is effective with capillary columns, but it is limited to a single bandcompression step and can only be achieved at the inlet. Here we evaluate multiplicative temperature-assisted solute focusing using a linear array of ten independently controlled 1.0 × 1.0 cm thermoelectric cooling elements (TECs) to generate dynamic temperature changes along the length of the column. The evaluation has two prongs: simulation and experimental. Simulation is required to understand the effect of a particular temperature change at a particular place and time on the column to determine optimal timing of temperature changes. Because the accuracy of the simulations is good, as long as the effect of temperature on retention factor is known, experimental conditions required to achieve a particular focusing objective can be estimated. We evaluated the capability of the technique to selectively focus only one of two solutes. This was achieved using three adjacent zones with temperature controlled by (upstream first) four, two, and one TECs. The three focusing steps occurring on column gave a 20-fold increase in peak height without solvent-based focusing for a solute with modest retention enthalpy.

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Electroosmotic Perfusion, External Microdialysis: Simulation and Experiment

Rerick

Chen

Weber

2023

ACS Chem. Neurosci.

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Information about the rates of hydrolysis of neuropeptides by extracellular peptidases can lead to a quantitative understanding of how the steady-state and transient concentrations of neuropeptides are controlled. We have created a small microfluidic device that electroosmotically infuses peptides into, through, and out of the tissue to a microdialysis probe outside the head. The device is created by two-photon polymerization (Nanoscribe). Inferring quantitative estimates of a rate process from the change in concentration of a substrate that has passed through tissue is challenging for two reasons. One is that diffusion is significant, so there is a distribution of peptide substrate residence times in the tissue. This affects the product yield. The other is that there are multiple paths taken by the substrate as it passes through tissue, so there is a distribution of residence times and thus reaction times. Simulation of the process is essential. The simulations presented here imply that a range of first order rate constants of more than 3 orders of magnitude is measurable and that 5−10 min is required to reach a steady state value of product concentration following initiation of substrate infusion. Experiments using a peptidaseresistant D-amino acid pentapeptide, yaGfl, agree with simulations.

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Michael T. Rerick

Electroosmotic Perfusion–Microdialysis Probe Created by Direct Laser Writing for Quantitative Assessment of Leucine Enkephalin Hydrolysis by Insulin-Regulated Aminopeptidase in Vivo

Validation of Dexamethasone-Enhanced Continuous-Online Microdialysis for Monitoring Glucose for 10 Days after Brain Injury

Multiplicative On-Column Solute Focusing Using Spatially Dependent Temperature Programming for Capillary HPLC

Electroosmotic Perfusion, External Microdialysis: Simulation and Experiment

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