A microfluidic perspective on conventional in vitro transcranial direct current stimulation methods

“…Some studies have shown that a dcEF intensity as low as 0.75 mV mm −1 could trigger long-term potentiation (LTP) like effects 31 and 4.7 mV mm −1 is within this neural activation range. 16,46 According to our recent technical review, 32 it is highly possible that the actual EF intensities used in these studies were higher than 4.7 mV mm −1 , due to a systematic underestimation of dcEF intensity in these studies using conventional calibration approaches. [24][25][26]68 Voroslakos and colleagues have also raised the opinion that the intensity needed for exerting active tDCS effects should be higher than regularly reported literature values.…”

“…Meanwhile, the prevalent system of stimulating acute slices with parallel electrodes in elaborate electrophysiological setups is not satisfying regarding its limitations in delivering precise dcEF around brain tissue or obtaining results over a relatively long time course. 32 To address these issues, we developed an inexpensive and high-throughput solution using microfluidic techniques to achieve precise control of uniform EFs in space and time. We displayed various application scenarios using organotypic tissue cultures by extending experiment durations and accommodating cutting-edge probing techniques.…”

“…S1). 32 Meanwhile, this control is fundamental to studying dose-dependent and EF orientation-related neural mechanisms. Therefore, we leveraged the microchannel design used in cell electrotaxis experiments 39,40 to create a microfluidic chamber with ge- (i) Live-cell imaging and dcEF of slices within the microfluidic chamber.…”

“…The stimulation electrode material is another factor to consider for delivering constant DC with minimal electrochemically-generated species, which are side reactions to the DC. 32,42 Here, non-metal supercapacitive electrodes (laser-induced graphene coated with the conducting hydrogel PEDOT:PSS) were used. 43 Slow cyclic voltammetry (CV) was used to assess the capacitance of the electrode (Supplemental Note S1 and Fig.…”

“…Our recent review scrutinized these sophisticated setups and revealed their inability to precisely control the electric field (EF) and the risk of negative DC stimulation by-products. 32 The short lifetime of acute slices prevents researchers from studying the effects of repetitive EF stimulation (e.g., several sessions per day) or revisiting the neural tissue hours or days after EF stimulation. Some studies have attempted 4 to address this by placing parallel electrodes inside six-well plates to stimulate tissue or cells inside the incubator, 33,34 while a lack of precise EF control and inevitable electrochemical faradaic reactions still remained.…”

On-chip brain slice stimulation: precise control of electric fields and tissue orientation

“…Some studies have shown that a dcEF intensity as low as 0.75 mV mm −1 could trigger long-term potentiation (LTP) like effects 31 and 4.7 mV mm −1 is within this neural activation range. 16,46 According to our recent technical review, 32 it is highly possible that the actual EF intensities used in these studies were higher than 4.7 mV mm −1 , due to a systematic underestimation of dcEF intensity in these studies using conventional calibration approaches. [24][25][26]68 Voroslakos and colleagues have also raised the opinion that the intensity needed for exerting active tDCS effects should be higher than regularly reported literature values.…”

“…Meanwhile, the prevalent system of stimulating acute slices with parallel electrodes in elaborate electrophysiological setups is not satisfying regarding its limitations in delivering precise dcEF around brain tissue or obtaining results over a relatively long time course. 32 To address these issues, we developed an inexpensive and high-throughput solution using microfluidic techniques to achieve precise control of uniform EFs in space and time. We displayed various application scenarios using organotypic tissue cultures by extending experiment durations and accommodating cutting-edge probing techniques.…”

“…S1). 32 Meanwhile, this control is fundamental to studying dose-dependent and EF orientation-related neural mechanisms. Therefore, we leveraged the microchannel design used in cell electrotaxis experiments 39,40 to create a microfluidic chamber with ge- (i) Live-cell imaging and dcEF of slices within the microfluidic chamber.…”

“…The stimulation electrode material is another factor to consider for delivering constant DC with minimal electrochemically-generated species, which are side reactions to the DC. 32,42 Here, non-metal supercapacitive electrodes (laser-induced graphene coated with the conducting hydrogel PEDOT:PSS) were used. 43 Slow cyclic voltammetry (CV) was used to assess the capacitance of the electrode (Supplemental Note S1 and Fig.…”

“…Our recent review scrutinized these sophisticated setups and revealed their inability to precisely control the electric field (EF) and the risk of negative DC stimulation by-products. 32 The short lifetime of acute slices prevents researchers from studying the effects of repetitive EF stimulation (e.g., several sessions per day) or revisiting the neural tissue hours or days after EF stimulation. Some studies have attempted 4 to address this by placing parallel electrodes inside six-well plates to stimulate tissue or cells inside the incubator, 33,34 while a lack of precise EF control and inevitable electrochemical faradaic reactions still remained.…”

On-chip brain slice stimulation: precise control of electric fields and tissue orientation

Bioelectronic Direct Current Stimulation at the Transition Between Reversible and Irreversible Charge Transfer

How conductivity boundaries influence the electric field induced by transcranial magnetic stimulation in in vitro experiments