Combined in vivo recording of neural signals and iontophoretic injection of pathway tracers using a hollow silicon microelectrode

Fekete, Zoltán; Pálfi, Emese; Márton, Gergely; Handbauer, M.; Bérces, Zs.; Ulbert, István; Pongrácz, Anita; Négyessy, László

doi:10.1016/j.snb.2015.12.099

Cited by 8 publications

(5 citation statements)

References 28 publications

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“…Future developments may enable such devices to be applied in both chronic and acute recordings, as well as in combination with other modalities such as intracellular recordings, combined optogenetics or microfluidic drug delivery applications [59], [60]. We showed an example for combined two-photon imaging and proposed that our spiky probe makes possible consecutive recording and imaging of the tissue at the same region.…”

Section: Discussionmentioning

confidence: 99%

A silicon-based spiky probe providing improved cell accessibility during in vitro slice recordings

Meszéna

Kerekes

Pál

et al. 2019

Sensors and Actuators B: Chemical

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Aims. In this study, we introduce an edge-type laminar silicon probe suitable for improved cell accessibility during in vitro brain slice recordings. With protruding contact sites, the spiky probe provides high signal yield and quality while approaching cells located deeper in the tissue.Methods. The spiky probe comprises an angled shank carrying 32 protruding contact sites with three possible spacing of 25 µm, 50 µm and 100 µm. The angled shank makes the probe compatible with large microscope objectives used typically in two-photon imaging, in vitro.Spiky probes were batch manufactured with high precision using the etching before grinding technology and bonded to a custom designed printed circuit board. A quantitative comparison of the performance was made against a commercially available surface probe. To investigate the long-term stability of contact sites, the spiky probe was repeatedly inserted in seven experiments (17 insertions, in total) using Wistar rat hippocampal slices, in vitro. Impedance magnitudes and phase angles were compared before and after the extensive usage.Results. Single unit activities were recorded with higher neuronal yield and higher amplitudes compared to the surface probe. Impedances did not increase significantly after reusing the probe in multiple experiments. Furthermore, we were able to detect extracellular action potentials from the same single unit on multiple, adjacent contact sites. Finally, we separated the recorded single units into putative cell types based on their extracellular waveforms. Conclusion and outlook.The spiky probes were proved to be optimal solutions to record extracellular spike waveforms, in vitro. The improved signal quality allowed us to distinguish between putative interneurons and principal cells. In future works, integrative experiments using these probes may provide multi-modal data for cellular electrophysiology resulting in a deeper understanding of single cell contributions to mass neural activity.

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Section: Discussionmentioning

confidence: 99%

A silicon-based spiky probe providing improved cell accessibility during in vitro slice recordings

Meszéna

Kerekes

Pál

et al. 2019

Sensors and Actuators B: Chemical

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“…The parylene tube can also function as a microfluidic channel for chemical delivery. Such a capability is highly desirable for probing neural circuits as demonstrated by others [13,14]. Thanks to the transparency of parylene, an optical fiber can be inserted (figure 8), enabling the delivery of light to deep brain structures for optogenetic modulation.…”

Section: Discussionmentioning

confidence: 99%

“…Ultra-long silicon probes with integrated microchannels have been developed as well by Fekete and others [11,12]. Successful in vivo animal tests have been demonstrated using these multi-functional deep brain probes [13,14]. The fracture of ultra-long silicon probes with integrated microchannels has also been studied [11].…”

Section: Introductionmentioning

confidence: 99%

Flexible deep brain neural probes based on a parylene tube structure

Zhao

Kim

Luo

et al. 2017

J. Micromech. Microeng.

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Most microfabricated neural probes have limited shank length, which prevents them from reaching many deep brain structures. This paper reports deep brain neural probes with ultra-long penetrating shanks based on a simple but novel parylene tube structure. The mechanical strength of the parylene tube shank is temporarily enhanced during implantation by inserting a metal wire. The metal wire can be removed after implantation, making the implanted probe very flexible and thus minimizing the stress caused by micromotions of brain tissues. Optogenetic stimulation and chemical delivery capabilities can be potentially integrated by taking advantage of the tube structure. Single-shank prototypes with a shank length of 18.2 mm have been developed. The microfabrication process comprises of deep reactive ion etching (DRIE) of silicon, parylene conformal coating/refilling, and XeF2 isotropic silicon etching. In addition to bench-top insertion characterization, the functionality of developed probes has been preliminarily demonstrated by implanting into the amygdala of a rat and recording neural signals.

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“…A drug delivery system is installed in the electrode to inject drugs locally. Biotinylated dextran amine (BDA), which is a neuronal tracer used both for anterograde and retrograde, is delivered locally using iontophoresis to find out the recording position [ 83 ]. Also, after dexamethasone, an anti-inflammatory drug, was loaded in the conducting polymer to inject only the electrode site, the signal was measured for more than 12 weeks [ 84 ].…”

Section: Penetrating Electrode For In Vivo Applicationsmentioning

confidence: 99%

Recent Progress on Microelectrodes in Neural Interfaces

Kim

Lee

et al. 2018

Materials

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Brain‒machine interface (BMI) is a promising technology that looks set to contribute to the development of artificial limbs and new input devices by integrating various recent technological advances, including neural electrodes, wireless communication, signal analysis, and robot control. Neural electrodes are a key technological component of BMI, as they can record the rapid and numerous signals emitted by neurons. To receive stable, consistent, and accurate signals, electrodes are designed in accordance with various templates using diverse materials. With the development of microelectromechanical systems (MEMS) technology, electrodes have become more integrated, and their performance has gradually evolved through surface modification and advances in biotechnology. In this paper, we review the development of the extracellular/intracellular type of in vitro microelectrode array (MEA) to investigate neural interface technology and the penetrating/surface (non-penetrating) type of in vivo electrodes. We briefly examine the history and study the recently developed shapes and various uses of the electrode. Also, electrode materials and surface modification techniques are reviewed to measure high-quality neural signals that can be used in BMI.

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Combined in vivo recording of neural signals and iontophoretic injection of pathway tracers using a hollow silicon microelectrode

Cited by 8 publications

References 28 publications

A silicon-based spiky probe providing improved cell accessibility during in vitro slice recordings

A silicon-based spiky probe providing improved cell accessibility during in vitro slice recordings

Flexible deep brain neural probes based on a parylene tube structure

Recent Progress on Microelectrodes in Neural Interfaces

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