Your search keyword '"Wang, Jingxuan"' showing total 5 results

1. Effect of shorter pulse duration in cochlear neural activation with an 810-nm near-infrared laser.

Author

Wang J, Tian L, Lu J, Xia M, and Wei Y

Subjects

Animals, Cochlea radiation effects, Evoked Potentials, Auditory, Brain Stem radiation effects, Female, Guinea Pigs, Male, Optical Fibers, Time Factors, Cochlea innervation, Cochlear Nerve physiology, Cochlear Nerve radiation effects, Infrared Rays, Lasers

Abstract

Optical neural stimulation in the cochlea has been presented as an alternative technique to the electrical stimulation due to its potential in spatially selectivity enhancement. So far, few studies have selected the near-infrared (NIR) laser in cochlear neural stimulation and limited optical parameter space has been examined. This paper focused on investigating the optical parameter effect on NIR stimulation of auditory neurons, especially under shorter pulse durations. The spiral ganglion neurons in the cochlea of deafened guinea pigs were stimulated with a pulsed 810-nm NIR laser in vivo. The laser radiation was delivered by an optical fiber and irradiated towards the modiolus. Optically evoked auditory brainstem responses (OABRs) with various optical parameters were recorded and investigated. The OABRs could be elicited with the cochlear deafened animals by using the 810-nm laser in a wide pulse duration ranged from 20 to 1000 μs. Results showed that the OABR intensity increased along with the increasing laser radiant exposure of limited range at each specific pulse duration. In addition, for the pulse durations from 20 to 300 μs, the OABR intensity increased monotonically along with the pulse duration broadening. While for pulse durations above 300 μs, the OABR intensity basically kept stable with the increasing pulse duration. The 810-nm NIR laser could be an effective stimulus in evoking the cochlear neuron response. Our experimental data provided evidence to optimize the pulse duration range, and the results suggested that the pulse durations from 20 to 300 μs could be the optimized range in cochlear neural activation with the 810-nm-wavelength laser.

Published

2017

2. Effect of Fiberoptic Collimation Technique on 808 nm Wavelength Laser Stimulation of Cochlear Neurons.

Author

Wang J, Lu J, and Tian L

Subjects

Animals, Evoked Potentials, Auditory, Brain Stem, Guinea Pigs, Acoustic Stimulation methods, Cochlea radiation effects, Cochlear Nerve radiation effects, Fiber Optic Technology, Infrared Rays, Lasers, Neurons radiation effects

Abstract

Objective: The purpose of this study was to evaluate the effects of fiberoptic collimation technique on auditory neural stimulation in the cochlea with 808 nm wavelength lasers., Background Data: Recently, the pulsed near-infrared lasers in the 800-1000 nm wavelength range have been investigated as an emerging technique to trigger auditory neural response in the cochlea. A laser beam divergence in the optical stimulation pathway exists, which may affect stimulation efficiency and spatial selectivity., Methods: The fiberoptic collimation technique was proposed for cochlear neuron stimulation, and the C-lens element was designed as the collimation structure. The spiral ganglion cells in deafened guinea pigs' cochlea were irradiated with collimated and uncollimated near-infrared lasers. Optically evoked auditory brainstem response (OABR) under the two laser output modes were recorded., Results: Laser with the collimation technique evoked an average 58% higher OABR amplitude than the uncollimated laser output. In addition, the collimated laser setup consumed on average 35.2% of laser energy compared with the uncollimated laser when evoking the same OABR amplitude., Conclusions: The fiberoptic collimation technique improved stimulation efficiency and reduced stimulating energy consumption in near-infrared neural stimulation in cochlea. The positive effects of laser collimation technique could benefit further research in optically based cochlear implants.

Published

2016

3. Pulsed 980 nm short wavelength infrared neural stimulation in cochlea and laser parameter effects on auditory response characteristics.

Author

Wang J, Lu J, Li C, Xu L, Li X, and Tian L

Subjects

Acoustic Stimulation instrumentation, Animals, Brain Stem cytology, Brain Stem physiology, Cochlea cytology, Cochlear Nerve cytology, Deafness pathology, Deafness physiopathology, Guinea Pigs, Neurons cytology, Optical Fibers, Acoustic Stimulation methods, Cochlea physiology, Cochlear Nerve physiology, Infrared Rays, Lasers

Abstract

Background: Auditory neural stimulation with pulsed infrared radiation has been proposed as an alternative method to activate the auditory nerves in vivo. Infrared wavelengths from 1800-2150 nm with high water absorption were mainly selected in previous studies. However, few researchers have used the short-wavelength infrared (SWIR) for auditory nerve stimulation and limited pulse parameters variability has been investigated so far., Methods: In this paper, we pioneered to use the 980 nm SWIR laser with adjustable pulse parameter as a stimulus to act on the deafened guinea pigs' cochlea in vivo. Pulsed laser light was guided through the cochlear round window to irradiate the spiral ganglion cells via a 105 μm optical fiber, and then the laser pulse parameters variability and its influence to auditory response characteristics were studied., Results: The results showed that the optically evoked auditory brainstem response (OABR) had a similar waveform to the acoustically induced ABR with click sound stimulus. And the evoked OABR amplitude had a positive correlation, while the OABR latency period showed a negative correlation, with the laser pulse energy increase. However, when holding the laser peak power constant, the pulse width variability ranged from 100 to 800 μs showed little influence on the evoked OABR amplitude and its latency period., Conclusions: Our study suggests that 980 nm SWIR laser is an effective stimulus for auditory neurons activation in vivo. The evoked OABR amplitude and latency are highly affected by the laser pulse energy, while not sensitive to the pulse width variability in 100-800 μs range.

Published

2015

4. Short-wavelength infrared laser activates the auditory neurons: comparing the effect of 980 vs. 810 nm wavelength

Author

Tian, Lan, Wang, Jingxuan, Wei, Ying, Lu, Jianren, Xu, Anting, and Xia, Ming

Published

2017

5. Pulsed 980 nm short wavelength infrared neural stimulation in cochlea and laser parameter effects on auditory response characteristics.

Author

Jingxuan Wang, Jianren Lu, Chen Li, Lei Xu, Xiaofei Li, Lan Tian, Wang, Jingxuan, Lu, Jianren, Li, Chen, Xu, Lei, Li, Xiaofei, and Tian, Lan

Subjects

PULSED radiation, INFRARED radiation, WAVELENGTHS, NEURAL stimulation, COCHLEA, ACOUSTIC nerve, AUDITORY evoked response, BRAIN stem physiology, COCHLEA physiology, MEDICAL equipment, ANIMAL experimentation, BRAIN stem, DEAFNESS, GUINEA pigs, LASERS, NONIONIZING radiation, NEURONS, EQUIPMENT & supplies, ACOUSTIC stimulation, PHYSIOLOGY

Abstract

Background: Auditory neural stimulation with pulsed infrared radiation has been proposed as an alternative method to activate the auditory nerves in vivo. Infrared wavelengths from 1800-2150 nm with high water absorption were mainly selected in previous studies. However, few researchers have used the short-wavelength infrared (SWIR) for auditory nerve stimulation and limited pulse parameters variability has been investigated so far.Methods: In this paper, we pioneered to use the 980 nm SWIR laser with adjustable pulse parameter as a stimulus to act on the deafened guinea pigs' cochlea in vivo. Pulsed laser light was guided through the cochlear round window to irradiate the spiral ganglion cells via a 105 μm optical fiber, and then the laser pulse parameters variability and its influence to auditory response characteristics were studied.Results: The results showed that the optically evoked auditory brainstem response (OABR) had a similar waveform to the acoustically induced ABR with click sound stimulus. And the evoked OABR amplitude had a positive correlation, while the OABR latency period showed a negative correlation, with the laser pulse energy increase. However, when holding the laser peak power constant, the pulse width variability ranged from 100 to 800 μs showed little influence on the evoked OABR amplitude and its latency period.Conclusions: Our study suggests that 980 nm SWIR laser is an effective stimulus for auditory neurons activation in vivo. The evoked OABR amplitude and latency are highly affected by the laser pulse energy, while not sensitive to the pulse width variability in 100-800 μs range. [ABSTRACT FROM AUTHOR]

Published

2015