Localized Drug Application and Sub-Second Voltammetric Dopamine Release Measurements in a Brain Slice Perfusion Device

Sun, Meng; Kaplan, Sam V.; Gehringer, Rachel C.; Limbocker, Ryan; Johnson, Michael A.

doi:10.1021/ac5008927

Cited by 18 publications

(12 citation statements)

References 41 publications

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“…Some typical examples include the fabrication of a 4‐channel intracorticol glassy carbon microelectrode array incorporated on a flexible substrate, [ 231 ] a wearable electrochemical recording device for the real‐time detection of neurotransmitters, [ 232 ] and a perfusion device incorporated with a microcapillary for the detection of neurotransmitters released by brain slices. [ 233 ] Metal oxides have also proven as an efficient material for the in vivo analysis of neurotransmitters. As a reference, nanostructured SnO 2 integrated conductive carbon yarns were developed as binder‐free electrodes for the detection of neurotransmitters, which can be further developed as wearable electrochemical sensors.…”

Section: Future Perspectives Of Electrochemical Detection Of Neurotransmittersmentioning

confidence: 99%

Transition metal oxide based non‐enzymatic electrochemical sensors: An arising approach for the meticulous detection of neurotransmitter biomarkers

Poolakkandy

Menamparambath

2020

Electrochemical Science Adv

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Diagnosis of brain disorders is an extremely confronting task for the medical community and hence, the recognition and detection of pertinent biomarkers for neurological disorders is a crucial phase. Electrochemical techniques with transition metal oxide (TMOs) modified electrodes have emerged as a promising technique for the detection of neurotransmitters, which act as potent biomarkers. This review has tried to sum up the recent advancements made in the TMOs modified non-enzymatic electrochemical detection of important neurotransmitters in the last two decades. A comprehensive description of these neurotransmitters along with their biochemistry and impact on the human body is also provided. A short description of the future perspectives of the electrochemical detection of neurotransmitters is given highlighting the wearable sensors for the in vivo detection.

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Section: Future Perspectives Of Electrochemical Detection Of Neurotransmittersmentioning

confidence: 99%

Transition metal oxide based non‐enzymatic electrochemical sensors: An arising approach for the meticulous detection of neurotransmitter biomarkers

Poolakkandy

Menamparambath

2020

Electrochemical Science Adv

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“…Thus, these models allow for the reproduction of synaptic competition [ 105 ], cell line authentication [ 92 , 93 ], study of neuronal migration in embryonic brain explants [ 95 ], axonal guidance during brain development [ 93 ] ( Figure 1 C) and myelination [ 94 ]. The use of brain explants within microfluidic devices also allows for the exposure to multiple compounds at once or in sequence, thus improving the existent models towards an individual medicine approach as a guided therapeutic decision-making [ 100 , 104 , 108 ]. Of great interest is the possibility to exploit microfluidics for high-throughput mapping of brain-wide activity in awake and drug-responsive vertebrates (e.g., zebrafish) [ 101 ].…”

Section: Convergence Between Microfluidics and Tissue Engineering:mentioning

confidence: 99%

Microfluidic Organ/Body-on-a-Chip Devices at the Convergence of Biology and Microengineering

Perestrelo

Águas

Rainer

et al. 2015

Sensors

130

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Recent advances in biomedical technologies are mostly related to the convergence of biology with microengineering. For instance, microfluidic devices are now commonly found in most research centers, clinics and hospitals, contributing to more accurate studies and therapies as powerful tools for drug delivery, monitoring of specific analytes, and medical diagnostics. Most remarkably, integration of cellularized constructs within microengineered platforms has enabled the recapitulation of the physiological and pathological conditions of complex tissues and organs. The so-called “organ-on-a-chip” technology, which represents a new avenue in the field of advanced in vitro models, with the potential to revolutionize current approaches to drug screening and toxicology studies. This review aims to highlight recent advances of microfluidic-based devices towards a body-on-a-chip concept, exploring their technology and broad applications in the biomedical field.

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“…In both cases, the voltammetric protocol provided direct and reliable assessment of the drug releasing kinetics profile. Voltammetric techniques have also been used to study releasing of different species from living cells 13 and dopamine releasing from brain tissue slices 14. In addition, a recent work has described the use of multiple pulse amperometry to directly study the in‐vitro doxorubicin releasing profile from therapeutic nanoparticles 15.…”

Section: Introductionmentioning

confidence: 99%

Square‐Wave Voltammetry as Analytical Tool for Real‐Time Study of Controlled Naproxen Releasing from Cellulose Derivative Materials

et al. 2015

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This work reports the successful use of square‐wave voltammetry (SWV) to directly assess the controlled releasing profile of naproxen from lab‐made cellulose derivative materials (membranes and microparticles) in phosphate buffer (pH 7.4) at 36 °C. Particular advantage of SWV refers to the direct real‐time monitoring of released drug from cellulose derivative microparticles, which cannot be easily assessed by UV‐spectrophotometry. Moreover, SWV was able to detect modifications in the naproxen releasing profile due to morphology and processing of membranes and microparticles. The possible miniaturization and versatility of SWV suggest the promising application on the study of several drug delivery systems, including in vivo studies.

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Localized Drug Application and Sub-Second Voltammetric Dopamine Release Measurements in a Brain Slice Perfusion Device

Cited by 18 publications

References 41 publications

Transition metal oxide based non‐enzymatic electrochemical sensors: An arising approach for the meticulous detection of neurotransmitter biomarkers

Transition metal oxide based non‐enzymatic electrochemical sensors: An arising approach for the meticulous detection of neurotransmitter biomarkers

Microfluidic Organ/Body-on-a-Chip Devices at the Convergence of Biology and Microengineering

Square‐Wave Voltammetry as Analytical Tool for Real‐Time Study of Controlled Naproxen Releasing from Cellulose Derivative Materials

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