Katrien Maes scite author profile

Neuropeptides seem to play an important role when the CNS is challenged. In order to obtain better insights into the central peptidergic effects, it is essential to monitor their concentration in the brain. Quantification of neuropeptides in dialysates is challenging due to their low extracellular concentrations (low pM range), their low microdialysis efficiencies, the need for acceptable temporal resolution, the small sample volumes, the complexity of the matrix and the tendency of peptides to stick to glass and polymeric materials. The quantification of neuropeptides in dialysates therefore necessitates the use of very sensitive nano-LC-MS/MS methods. A number of LC-MS/MS and microdialysis parameters need to be optimized to achieve maximal sensitivity. The optimized and validated methods can be used to investigate the in vivo neuropeptide release during pathological conditions, in this way initiating new and immense challenges for the development of new drugs.

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Predicting the headspace oxygen level due to oxygen permeation across multilayer polymer packaging materials: A practical software simulation tool

Bree

Meulenaer

Samapundo

et al. 2010

Innovative Food Science & Emerging Technologies

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Modelling the electro-osmotically enhanced pressure dewatering of activated sludge

Curvers

Maes

Saveyn

et al. 2007

Chemical Engineering Science

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An Ultrasensitive Nano UHPLC–Esi–MS/MS Method for The Quantification of Three Neuromedin-Like Peptides in Microdialysates

et al. 2015

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Aim: An ultrasensitive nano UHPLC–ESI–MS/MS method is developed to simultaneously monitor three low-concentration neuromedin-like peptides in microdialysates. Results: Peptide preconcentration and sample desalting is performed online on a trap column. A shallow gradient slope at 300 nl/min on the analytical column maintained at 35°C, followed by two saw-tooth column wash cycles, results in the highest sensitivity and the lowest carryover. The validated method allows the accurate and precise quantification of 0.5 pM neurotensin and neuromedin N (2.5 amol on column), and of 3.0 pM neuromedin B (15.0 amol on column) in in vivo microdialysates without the use of internal standards. Conclusion: The assay is an important tool for elucidating the role of these neuromedin-like peptides in the pathophysiology of neurological disorders.

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Critical aspects for the reliable headspace analysis of plants cultivated in vitro

Maes

Vercammen

Pham-Tuan

et al. 2001

Phytochemical Analysis

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Katrien Maes

Strategies to reduce aspecific adsorption of peptides and proteins in liquid chromatography–mass spectrometry based bioanalyses: An overview

Improved sensitivity of the nano ultra-high performance liquid chromatography-tandem mass spectrometric analysis of low-concentrated neuropeptides by reducing aspecific adsorption and optimizing the injection solvent

Validation of the 6Hz refractory seizure mouse model for intracerebroventricularly administered compounds

The Absolute Quantification of Endogenous Levels of Brain Neuropeptides In Vivo Using LC–MS/MS

Predicting the headspace oxygen level due to oxygen permeation across multilayer polymer packaging materials: A practical software simulation tool

Modelling the electro-osmotically enhanced pressure dewatering of activated sludge

An Ultrasensitive Nano UHPLC–Esi–MS/MS Method for The Quantification of Three Neuromedin-Like Peptides in Microdialysates

Critical aspects for the reliable headspace analysis of plants cultivated in vitro

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