Laser Stimulation of Auditory Neurons: Effect of Shorter Pulse Duration and Penetration Depth

Izzo, Agnella D.; Walsh, Joseph T.; Ralph, Heather; Webb, Jim; Bendett, Mark; Wells, Jonathon; Richter, Claus Peter

doi:10.1529/biophysj.107.117150

Cited by 158 publications

(196 citation statements)

References 39 publications

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“…This study explored the effects of temperature changes on membrane capacitance and its associated currents in a joint attempt to clarify the experimental results of a key recent study [16] and to pave the way towards predictive modeling of INS [2][3][4][5][6][7][8][9][10][11][12][13][14][15] and other thermal neurostimulation techniques [18][19][20], which could potentially facilitate the development of more advanced and multimodal methods for neural circuit control. Another key motivation to pursue this problem came from our noting the very similar temperature-related capacitance rates of change observed in very different model systems [ Fig.…”

Section: Discussionmentioning

confidence: 99%

“…Both approaches also offer the long-term prospect of remotely affecting aberrant localized neural circuits that underlie many neurological diseases. A multitude of INS-related studies explored the ability of short-wave infrared (IR) pulses to stimulate neural structures including peripheral [3,4] and cranial nerves [5][6][7][8][9][10], retinal and cortical neurons [10][11][12], as well as cardiomyocytes [13,14]. It is stipulated that the INS phenomenon is mediated by temperature transients induced by IR absorption [15][16][17]; such transients can alternatively be induced using other forms of photoabsorption [18][19][20], or potentially by any other physical form of thermal neurostimulation that can be driven rapidly enough [21,22].…”

Section: Introductionmentioning

confidence: 99%

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Thermal Transients Excite Neurons through Universal Intramembrane Mechanoelectrical Effects

et al. 2018

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Modern advances in neurotechnology rely on effectively harnessing physical tools and insights towards remote neural control, thereby creating major new scientific and therapeutic opportunities. Specifically, rapid temperature pulses were shown to increase membrane capacitance, causing capacitive currents that explain neural excitation, but the underlying biophysics is not well understood. Here, we show that an intramembrane thermal-mechanical effect wherein the phospholipid bilayer undergoes axial narrowing and lateral expansion accurately predicts a potentially universal thermal capacitance increase rate of ∼0.3%=°C. This capacitance increase and concurrent changes in the surface charge related fields lead to predictable exciting ionic displacement currents. The new MechanoElectrical Thermal Activation theory's predictions provide an excellent agreement with multiple experimental results and indirect estimates of latent biophysical quantities. Our results further highlight the role of electro-mechanics in neural excitation; they may also help illuminate subthreshold and novel physical cellular effects, and could potentially lead to advanced new methods for neural control.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Thermal Transients Excite Neurons through Universal Intramembrane Mechanoelectrical Effects

et al. 2018

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“…Infrared stimulation was first developed in nerves [24] and has been used to stimulate a variety of nerves and neurons [25][26][27][28][29][30], vestibular hair cells [31], and isolated myocytes [32] using multimode fibers. Additionally, we have recently demonstrated the use of infrared stimulation to optically pace whole intact embryonic [33] and adult hearts [34].…”

Section: Introductionmentioning

confidence: 99%

Optical stimulation enables paced electrophysiological studies in embryonic hearts

Wang

et al. 2014

Biomed. Opt. Express

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Cardiac electrophysiology plays a critical role in the development and function of the heart. Studies of early embryonic electrical activity have lacked a viable point stimulation technique to pace in vitro samples. Here, optical pacing by high-precision infrared stimulation is used to pace excised embryonic hearts, allowing electrophysiological parameters to be quantified during pacing at varying rates with optical mapping. Combined optical pacing and optical mapping enables electrophysiological studies in embryos under more physiological conditions and at varying heart rates, allowing detection of abnormal conduction and comparisons between normal and pathological electrical activity during development in various models. 440-447 (1978). 12. K. Kamino, "Optical approaches to ontogeny of electrical activity and related functional organization during early heart development," Physiol. Rev. 71(1), 53-91 (1991 Macrae, and D. S. Rosenbaum, "The zebrafish as a novel animal model to study the molecular mechanisms of mechano-electrical feedback in the heart," Prog. Biophys. Mol. Biol. 110(2-3), 154-165 (2012). 18. M. Bressan, G. Liu, and T. Mikawa, "Early mesodermal cues assign avian cardiac pacemaker fate potential in a tertiary heart field," Science 340 (

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“…Compared to electrical stimulation, optical stimulation of the cochlea has attracted attention due to its high spatial precision, superior resolution, non-overlapping stimulation, with few stimulation artifacts or electrochemical interactions between the stimulation source and the tissue [2,3,20]. Previous studies on infrared laser auditory stimulation focused on cochlear functions by recording CAPs [3,8,11,14,21,22], and only a few studies measured oABRs evoked by optical stimulation in normal hearing animals [15,23]. The present study demonstrates that infrared laser pulses with wavelengths of 1850 nm could stimulate SGNs to evoke stable oABRs in both normal hearing and deafened guinea pigs.…”

Section: Discussionmentioning

confidence: 99%

“…Pulsed infrared lasers have been applied directly to evoke physiological responses in neuronal and other excitable cells both in vivo and in vitro without any prior genetic or chemical manipulation [4,5]. The targets of infrared lasers include peripheral and cranial motor nerves, vestibular hair cells, cochlear nerves, and the heart [6][7][8][9][10]. The advantage of direct infrared excitation makes it attractive for a variety of applications in basic and clinical research, ranging from hearing restoration to optical pacing [2].…”

Section: Introductionmentioning

confidence: 99%

Attenuated infrared neuron stimulation response in cochlea of deaf animals may associate with the degeneration of spiral ganglion neurons

Xie

Dai

2015

Biomed. Opt. Express

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Hypothesis: We hypothesize that degenerated spiral ganglion neurons (SGNs) in guinea pigs reduces auditory brainstem responses evoked by pulsed infrared stimulation. Background: Pulsed infrared laser excitation can directly evoke physiological responses in neuronal and other excitable cells in vivo and in vitro. Laser pulses could benefit patients with cochlear implants to stimulate the auditory system. Methods: Pulsed infrared lasers were used to study evoked optical auditory brainstem responses (oABRs) in normal hearing and deafened animals. Also, the morphology and anatomy of SGNs in normal hearing and deafened guinea pigs were compared. Results: By recording oABRs evoked by varying infrared laser pulse durations, it is suggested that degeneration of SGNs in deafened guinea pigs was associated with an elevated oABR threshold and with lower amplitudes. Moreover, oABR threshold decreased while amplitudes increased in both normal hearing and deafened animals as the pulse duration prolonged. Electron microscopy revealed that SGNs in deafened guinea pigs had swollen and vacuolar mitochondria, as well as demyelinated soma and axons. Conclusion: Infrared laser pulses can stimulate SGNs to evoke oABRs in guinea pigs. Deafened guinea pigs have elevated thresholds and smaller amplitude responses, likely a result of degenerated SGNs. Short pulse durations are more suitable to evoke responses in both normal hearing and deafened animals.

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Laser Stimulation of Auditory Neurons: Effect of Shorter Pulse Duration and Penetration Depth

Cited by 158 publications

References 39 publications

Thermal Transients Excite Neurons through Universal Intramembrane Mechanoelectrical Effects

Thermal Transients Excite Neurons through Universal Intramembrane Mechanoelectrical Effects

Optical stimulation enables paced electrophysiological studies in embryonic hearts

Attenuated infrared neuron stimulation response in cochlea of deaf animals may associate with the degeneration of spiral ganglion neurons

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