Your search keyword '"Takashi D. Y. Kozai"' showing total 6 results

1. In vivo spatiotemporal dynamics of NG2 glia activity caused by neural electrode implantation

Author

Takashi D. Y. Kozai and Steven M. Wellman

Subjects

Male, 0301 basic medicine, Cell type, Biophysics, Bioengineering, Article, Glial scar, Biomaterials, Mice, 03 medical and health sciences, 0302 clinical medicine, medicine, Animals, Antigens, Neuroinflammation, Microglia, biology, Chemistry, Neurodegeneration, Neurodegenerative Diseases, Multielectrode array, medicine.disease, Electrodes, Implanted, 030104 developmental biology, medicine.anatomical_structure, nervous system, Gliosis, Mechanics of Materials, Ceramics and Composites, biology.protein, Proteoglycans, medicine.symptom, Microelectrodes, Neuroglia, Neuroscience, 030217 neurology & neurosurgery, Neurotrophin

Abstract

Neural interface technology provides direct sampling and analysis of electrical and chemical events in the brain in order to better understand neuronal function and treat neurodegenerative disease. However, intracortical electrodes experience inflammatory reactions that reduce long-term stability and functionality and are understood to be facilitated by activated microglia and astrocytes. Emerging studies have identified another cell type that participates in the formation of a high-impedance glial scar following brain injury; the oligodendrocyte precursor cell (OPC). These cells maintain functional synapses with neurons and are a crucial source of neurotrophic support. Following injury, OPCs migrate toward areas of tissue injury over the course of days, similar to activated microglia. The delayed time course implicates these OPCs as key components in the formation of the outer layers of the glial scar around the implant. In vivo two-photon laser scanning microscopy (TPLSM) was employed to observe fluorescently-labeled OPC and microglia reactivity up to 72 h following probe insertion. OPCs initiated extension of cellular processes (2.5 ± 0.4 μm h −1) and cell body migration (1.6 ± 0.3 μm h−1 ) toward the probe beginning 12 h after insertion. By 72 h, OPCs became activated at a radius of about 190.3 μm away from the probe surface . This study characterized the early spatiotemporal dynamics of OPCs involved in the inflammatory response induced by microelectrode insertion. OPCs are key mediators of tissue health and are understood to have multiple fate potentials. Detailed spatiotemporal characterization of glial behavior under pathological conditions may allow identification of alternative intervention targets for mitigating the formation of a glial scar and subsequent neurodegeneration that debilitates chronic neural interfaces.

Published

2018

2. Ultrasoft microwire neural electrodes improve chronic tissue integration

Author

Takashi D. Y. Kozai, Silvia Luebben, Zhanhong Jeff Du, James Nabity, Shawn A. Sapp, Xin Sally Zheng, Christi L. Kolarcik, and X. Tracy Cui

Subjects

Male, Materials science, Deep brain stimulation, Surface chemistry of neural implants, Polymers, medicine.medical_treatment, Biomedical Engineering, Biocompatible Materials, Stimulation, 02 engineering and technology, Elastomer, Biochemistry, Tungsten, Article, Rats, Sprague-Dawley, Biomaterials, 03 medical and health sciences, 0302 clinical medicine, Subthalamic Nucleus, Materials Testing, medicine, Animals, Molecular Biology, Brain–computer interface, Inflammation, Neurons, Foreign-Body Reaction, technology, industry, and agriculture, Electric Conductivity, General Medicine, 021001 nanoscience & nanotechnology, Electric Stimulation, Electrodes, Implanted, Rats, Microelectrode, Brain implant, Blood-Brain Barrier, Electrode, Silicone Elastomers, 0210 nano-technology, Microelectrodes, 030217 neurology & neurosurgery, Biotechnology, Biomedical engineering

Abstract

Chronically implanted neural multi-electrode arrays (MEA) are an essential technology for recording electrical signals from neurons and/or modulating neural activity through stimulation. However, current MEAs, regardless of the type, elicit an inflammatory response that ultimately leads to device failure. Traditionally, rigid materials like tungsten and silicon have been employed to interface with the relatively soft neural tissue. The large stiffness mismatch is thought to exacerbate the inflammatory response. In order to minimize the disparity between the device and the brain, we fabricated novel ultrasoft electrodes consisting of elastomers and conducting polymers with mechanical properties much more similar to those of brain tissue than previous neural implants. In this study, these ultrasoft microelectrodes were inserted and released using a stainless steel shuttle with polyethyleneglycol (PEG) glue. The implanted microwires showed functionality in acute neural stimulation. When implanted for 1 or 8 weeks, the novel soft implants demonstrated significantly reduced inflammatory tissue response at week 8 compared to tungsten wires of similar dimension and surface chemistry. Furthermore, a higher degree of cell body distortion was found next to the tungsten implants compared to the polymer implants. Our results support the use of these novel ultrasoft electrodes for long term neural implants. Statement of Significance One critical challenge to the translation of neural recording/stimulation electrode technology to clinically viable devices for brain computer interface (BCI) or deep brain stimulation (DBS) applications is the chronic degradation of device performance due to the inflammatory tissue reaction. While many hypothesize that soft and flexible devices elicit reduced inflammatory tissue responses, there has yet to be a rigorous comparison between soft and stiff implants. We have developed an ultra-soft microelectrode with Young’s modulus lower than 1 MPa, closely mimicking the brain tissue modulus. Here, we present a rigorous histological comparison of this novel ultrasoft electrode and conventional stiff electrode with the same size, shape and surface chemistry, implanted in rat brains for 1-week and 8-weeks. Significant improvement was observed for ultrasoft electrodes, including inflammatory tissue reaction, electrode-tissue integration as well as mechanical disturbance to nearby neurons. A full spectrum of new techniques were developed in this study, from insertion shuttle to in situ sectioning of the microelectrode to automated cell shape analysis, all of which should contribute new methods to the field. Finally, we showed the electrical functionality of the ultrasoft electrode, demonstrating the potential of flexible neural implant devices for future research and clinical use.

Published

2017

3. Dexamethasone retrodialysis attenuates microglial response to implanted probes in vivo

Author

Takashi D. Y. Kozai, Adrian C. Michael, X. Tracy Cui, Andrea Jaquins-Gerstl, and Alberto L. Vazquez

Subjects

Genetically modified mouse, Microdialysis, Pathology, medicine.medical_specialty, Materials science, Anti-Inflammatory Agents, Biophysics, Mice, Transgenic, Bioengineering, Inflammation, 02 engineering and technology, Dexamethasone, Article, Biomaterials, 03 medical and health sciences, 0302 clinical medicine, In vivo, CX3CR1, medicine, Animals, Head Injuries, Penetrating, Microglia, Brain, Prostheses and Implants, 021001 nanoscience & nanotechnology, Cell biology, medicine.anatomical_structure, Mechanics of Materials, Ceramics and Composites, medicine.symptom, 0210 nano-technology, Perfusion, 030217 neurology & neurosurgery, medicine.drug

Abstract

Intracortical neural probes enable researchers to measure electrical and chemical signals in the brain. However, penetration injury from probe insertion into living brain tissue leads to an inflammatory tissue response. In turn, microglia are activated, which leads to encapsulation of the probe and release of pro-inflammatory cytokines. This inflammatory tissue response alters the electrical and chemical microenvironment surrounding the implanted probe, which may in turn interfere with signal acquisition. Dexamethasone (Dex), a potent anti-inflammatory steroid, can be used to prevent and diminish tissue disruptions caused by probe implantation. Herein, we report retrodialysis administration of dexamethasone while using in vivo two-photon microscopy to observe real-time microglial reaction to the implanted probe. Microdialysis probes under artificial cerebrospinal fluid (aCSF) perfusion with or without Dex were implanted into the cortex of transgenic mice that express GFP in microglia under the CX3CR1 promoter and imaged for 6 hours. Acute morphological changes in microglia were evident around the microdialysis probe. The radius of microglia activation was 177.1 μm with aCSF control compared to 93.0 μm with Dex perfusion. T-stage morphology and microglia directionality indices were also used to quantify the microglial response to implanted probes as a function of distance. Dexamethasone had a profound effect on the microglia morphology and reduced the acute activation of these cells.

Published

2016

4. Comprehensive chronic laminar single-unit, multi-unit, and local field potential recording performance with planar single shank electrode arrays

Author

Steven M. Chase, Matthew A. Smith, X. Tracy Cui, Robert M. Friedlander, Zhannetta V. Gugel, Zhanhong Du, Ellen M. Caparosa, Takashi D. Y. Kozai, and Lance Bodily

Subjects

Time Factors, Computer science, Rest, Analytical chemistry, Local field potential, Article, Planar, Electric Impedance, medicine, Animals, Layer (object-oriented design), Evoked Potentials, Visual Cortex, Neurons, General Neuroscience, Signal Processing, Computer-Assisted, Current source, Immunohistochemistry, Electrodes, Implanted, Mice, Inbred C57BL, Electrophysiology, Microelectrode, Visual cortex, medicine.anatomical_structure, Dielectric Spectroscopy, Electrode, Visual Perception, Microelectrodes, Photic Stimulation, Biomedical engineering

Abstract

Background: Intracortical electrode arrays that can record extracellular action potentials from small, targeted groups of neurons are critical for basic neuroscience research and emerging clinical applications. In general, these electrode devices suffer from reliability and variability issues, which have led to comparative studies of existing and emerging electrode designs to optimize performance. Comparisons of different chronic recording devices have been limited to single-unit (SU) activity and employed a bulk averaging approach treating brain architecture as homogeneous with respect to electrode distribution. New method: In this study, we optimize the methods and parameters to quantify evoked multi-unit (MU) and local field potential (LFP) recordings in eight mice visual cortices. Results: These findings quantify the large recording differences stemming from anatomical differences in depth and the layer dependent relative changes to SU and MU recording performance over 6-months. For example, performance metrics in Layer V and stratum pyramidale were initially higher than Layer II/III, but decrease more rapidly. On the other hand, Layer II/III maintained recording metrics longer. In addition, chronic changes at the level of layer IV are evaluated using visually evoked current source density. Comparison with existing method(s): The use of MU and LFP activity for evaluation and tracking biological depth provides a more comprehensive characterization of the electrophysiological performance landscape of microelectrodes. Conclusions: A more extensive spatial and temporal insight into the chronic electrophysiological performance over time will help uncover the biological and mechanical failure mechanisms of the neural electrodes and direct future research toward the elucidation of design optimization for specific applications.

Published

2015

5. Mechanical failure modes of chronically implanted planar silicon-based neural probes for laminar recording

Author

Alberto L. Vazquez, Takashi D. Y. Kozai, X. Tracy Cui, Valur Olafsson, Zhannetta V. Gugel, Xia Li, and Kasey Catt

Subjects

Silicon, Materials science, Scanning electron microscope, Finite Element Analysis, Biophysics, chemistry.chemical_element, Bioengineering, Article, Biomaterials, Planar, Electric Impedance, Electrode array, Animals, Cebus, Humans, Material failure theory, Brain, Magnetic Resonance Imaging, Electrodes, Implanted, Prosthesis Failure, Dielectric spectroscopy, Mice, Inbred C57BL, chemistry, Mechanics of Materials, Models, Animal, Electrode, Microscopy, Electron, Scanning, Ceramics and Composites, Stress, Mechanical, Material properties, Biomedical engineering

Abstract

Penetrating intracortical electrode arrays that record brain activity longitudinally are powerful tools for basic neuroscience research and emerging clinical applications. However, regardless of the technology used, signals recorded by these electrodes degrade over time. The failure mechanisms of these electrodes are understood to be a complex combination of the biological reactive tissue response and material failure of the device over time. While mechanical mismatch between the brain tissue and implanted neural electrodes have been studied as a source of chronic inflammation and performance degradation, the electrode failure caused by mechanical mismatch between different material properties and different structural components within a device have remained poorly characterized. Using Finite Element Model (FEM) we simulate the mechanical strain on a planar silicon electrode. The results presented here demonstrate that mechanical mismatch between iridium and silicon leads to concentrated strain along the border of the two materials. This strain is further focused on small protrusions such as the electrical traces in planar silicon electrodes. These findings are confirmed with chronic in vivo data (133–189 days) in mice by correlating a combination of single-unit electrophysiology, evoked multi-unit recordings, electrochemical impedance spectroscopy, and scanning electron microscopy from traces and electrode sites with our modeling data. Several modes of mechanical failure of chronically implanted planar silicon electrodes are found that result in degradation and/or loss of recording. These findings highlight the importance of strains and material properties of various subcomponents within an electrode array.

Published

2015

6. Effects of caspase-1 knockout on chronic neural recording quality and longevity: Insight into cellular and molecular mechanisms of the reactive tissue response

Author

Diane L. Carlisle, Takashi D. Y. Kozai, Lance Bodily, Ellen M. Caparosa, Georgios A. Zenonos, X. Tracy Cui, Robert M. Friedlander, and Xia Li

Subjects

medicine.medical_specialty, Programmed cell death, Pathology, Neural Prostheses, Biophysics, Caspase 1, Apoptosis, Bioengineering, Inflammation, Biology, Blood–brain barrier, Article, Biomaterials, Internal medicine, medicine, Animals, Mice, Knockout, Neurons, Foreign-Body Reaction, Brain, Cortex (botany), Mice, Inbred C57BL, Electrophysiology, medicine.anatomical_structure, Endocrinology, Gliosis, Mechanics of Materials, Ceramics and Composites, medicine.symptom

Abstract

Chronic implantation of microelectrodes into the cortex has been shown to lead to inflammatory gliosis and neuronal loss in the microenvironment immediately surrounding the probe, a hypothesized cause of neural recording failure. Caspase-1 (aka Interleukin 1β converting enzyme) is known to play a key role in both inflammation and programmed cell death, particularly in stroke and neurodegenerative diseases. Caspase-1 knockout (KO) mice are resistant to apoptosis and these mice have preserved neurologic function by reducing ischemia-induced brain injury in stroke models. Local ischemic injury can occur following neural probe insertion and thus in this study we investigated the hypothesis that caspase-1 KO mice would have less ischemic injury surrounding the neural probe. In this study, caspase-1 KO mice were implanted with chronic single shank 3 mm Michigan probes into V1m cortex. Electrophysiology recording showed significantly improved single-unit recording performance (yield and signal to noise ratio) of caspase-1 KO mice compared to wild type C57B6 (WT) mice over the course of up to 6 months for the majority of the depth. The higher yield is supported by the improved neuronal survival in the caspase-1 KO mice. Impedance fluctuates over time but appears to be steadier in the caspase-1 KO especially at longer time points, suggesting milder glia scarring. These findings show that caspase-1 is a promising target for pharmacologic interventions.

Published

2014