Dongmin Kim scite author profile

Organic electronic devices implemented on flexible thin films are attracting increased attention for biomedical applications because they possess extraordinary conformity to curved surfaces. A neuronal device equipped with an organic light-emitting diode (OLED), used in combination with animals that are genetically engineered to include a light-gated ion channel, would enable cell type-specific stimulation to neurons as well as conformal contact to brain tissue and peripheral soft tissue. This potential application of the OLEDs requires strong luminescence, well over the neuronal excitation threshold in addition to flexibility. Compatibility with neuroimaging techniques such as MRI provides a method to investigate the evoked activities in the whole brain. Here, we developed an ultrathin, flexible, MRI-compatible OLED device and demonstrated the activation of channelrhodopsin-2–expressing neurons in animals. Optical stimulation from the OLED attached to nerve fibers induced contractions in the innervated muscles. Mechanical damage to the tissues was significantly reduced because of the flexibility. Owing to the MRI compatibility, neuronal activities induced by direct optical stimulation of the brain were visualized using MRI. The OLED provides an optical interface for modulating the activity of soft neuronal tissues.

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Characteristics of magnetic probes for identifying sentinel lymph nodes

Ookubo

Inoue

Kim

et al. 2013

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The identification of the sentinel lymph nodes that cause tumor metastasis is important in breast cancer therapy. The detection of magnetic fluid accumulating in the lymph nodes using a magnetic probe allows surgeons to identify the lymph nodes. In this study, we carried out numerical simulations and experiments to investigate the sensitivity and basic characteristics of a magnetic probe consisting of a permanent magnet and a small magnetic sensor. The measured magnetic flux density arising from the magnetic fluid agreed well with the numerical results. In addition, the results helped realize an appropriate probe configuration for achieving high sensitivity to magnetic fluid. A prototype probe detected magnetic fluid located 30 mm from the probe head.

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Characteristics of bowl-shaped coils for transcranial magnetic stimulation

Yamamoto

Suyama

Takiyama

et al. 2015

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Transcranial magnetic stimulation (TMS) has recently been used as a method for the treatment of neurological and psychiatric diseases. Daily TMS sessions can provide continuous therapeutic effectiveness, and the installation of TMS systems at patients' homes has been proposed. A figure-eight coil, which is normally used for TMS therapy, induces a highly localized electric field; however, it is challenging to achieve accurate coil positioning above the targeted brain area using this coil. In this paper, a bowl-shaped coil for stimulating a localized but wider area of the brain is proposed. The coil's electromagnetic characteristics were analyzed using finite element methods, and the analysis showed that the bowl-shaped coil induced electric fields in a wider area of the brain model than a figure-eight coil. The expanded distribution of the electric field led to greater robustness of the coil to the coil-positioning error. To improve the efficiency of the coil, the relationship between individual coil design parameters and the resulting coil characteristics was numerically analyzed. It was concluded that lengthening the outer spherical radius and narrowing the width of the coil were effective methods for obtaining a more effective and more uniform distribution of the electric field.

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Finite-difference time-domain simulations of radio frequency electromagnetic fields and signal inhomogeneities in ultrahigh-field magnetic resonance imaging systems

Sekino

Kim

Ohsaki

2008

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Severe inhomogeneities of radio frequency electromagnetic fields arise in ultrahigh-field magnetic resonance imaging (MRI) systems. The purpose of this study is to estimate the distribution of electromagnetic fields, magnetic resonance signals, and the specific absorption ratio (SAR) in the human head. Numerical simulations were carried out using the finite-difference time-domain method. An increase in frequency resulted in severe inhomogeneities in the magnetic resonance signals and the SAR. A reduction in the duty ratio is required to meet safety standards for the SAR. The results indicate the importance of developing coils and image-processing methods to compensate for the signal inhomogeneities in proton images. On the other hand, ultrahigh-field MRI systems are particularly useful for quantitative measurements of nonproton nuclei.

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Dongmin Kim

Transparent, conformable, active multielectrode array using organic electrochemical transistors

Ultrasoft electronics to monitor dynamically pulsing cardiomyocytes

Integration of Organic Electrochemical and Field‐Effect Transistors for Ultraflexible, High Temporal Resolution Electrophysiology Arrays

A strain-absorbing design for tissue–machine interfaces using a tunable adhesive gel

Ultraflexible organic light-emitting diodes for optogenetic nerve stimulation

Characteristics of magnetic probes for identifying sentinel lymph nodes

Characteristics of bowl-shaped coils for transcranial magnetic stimulation

Finite-difference time-domain simulations of radio frequency electromagnetic fields and signal inhomogeneities in ultrahigh-field magnetic resonance imaging systems

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