Noninvasive Ultrasonic Neuromodulation in Freely Moving Mice

Li, Guofeng; Qiu, Weibao; Zhang, Zhiqiang; Jiang, Qinghua; Su, Min; Cai, Ruilin; Li, Yongchuan; Cai, Feiyan; Deng, Zhiting; Xu, Di; Zhang, Huailing; Zheng, Hairong

doi:10.1109/tbme.2018.2821201

Cited by 69 publications

(48 citation statements)

References 47 publications

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“…However, even for the larger animal, head-fixation was still required for the experiment. There exists only one study which reported neuromodulation of local field potential (LFP) using a miniature single-element transducer [16]. Since the same stimulation modality is preferred to translate the findings from pre-clinical to clinical trials, to observe…”

Section: Introductionmentioning

confidence: 99%

Miniature ultrasound ring array transducers for transcranial ultrasound neuromodulation of freely-moving small animals

Kim

Sim

et al. 2019

Brain Stimulation

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Section: Introductionmentioning

confidence: 99%

Miniature ultrasound ring array transducers for transcranial ultrasound neuromodulation of freely-moving small animals

Kim

Sim

et al. 2019

Brain Stimulation

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“…Electric impedance can be matched with simple shunt and series inductors to cancel the reactive component of the transducer [107][108][109]. Optimization of the EIMNs with driver/receiver electronics for broadband application in high-frequency range is difficult.…”

Section: Methods Of Electrical Impedance Matchingmentioning

confidence: 99%

A Review of Electric Impedance Matching Techniques for Piezoelectric Sensors, Actuators and Transducers

Rathod

2019

Electronics

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Any electric transmission lines involving the transfer of power or electric signal requires the matching of electric parameters with the driver, source, cable, or the receiver electronics. Proceeding with the design of electric impedance matching circuit for piezoelectric sensors, actuators, and transducers require careful consideration of the frequencies of operation, transmitter or receiver impedance, power supply or driver impedance and the impedance of the receiver electronics. This paper reviews the techniques available for matching the electric impedance of piezoelectric sensors, actuators, and transducers with their accessories like amplifiers, cables, power supply, receiver electronics and power storage. The techniques related to the design of power supply, preamplifier, cable, matching circuits for electric impedance matching with sensors, actuators, and transducers have been presented. The paper begins with the common tools, models, and material properties used for the design of electric impedance matching. Common analytical and numerical methods used to develop electric impedance matching networks have been reviewed. The role and importance of electrical impedance matching on the overall performance of the transducer system have been emphasized throughout. The paper reviews the common methods and new methods reported for electrical impedance matching for specific applications. The paper concludes with special applications and future perspectives considering the recent advancements in materials and electronics.

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“…Most of the previous works demonstrated ultrasound neuromodulation on immobile or sedated animals because commercially available transducers are often bulky, heavy, and requires a collimator [19][20][21][22][23][24][25]. Recently, three pioneering works on MEMS-based ultrasound transducers have successfully demonstrated in vivo neuromodulation in freely-moving behaving animals [38][39][40][41]. The first of these reports was based on a CMUT ring array composed of 32 elements with a 183-kHz resonant frequency [38,39].…”

Section: In Vivo Neurotoolsmentioning

confidence: 99%

“…The other two works were based on piezoelectric transducers (Table 1) [40,41]. Lee et al [41] developed a miniaturized tFUS system for freely-moving animals.…”

Section: In Vivo Neurotoolsmentioning

confidence: 99%

“…The developed freely-moving system was verified by performing tFUS in awake and anesthetized groups. Li et al [40] optimized the size of the PZT and produced piezoelectric transducers with 5 mm in diameter and 0.49 g in weight. By attaching a concave epoxy acoustic lens in front of the transducer, a lateral spatial resolution of 1.2 mm was achieved.…”

Section: In Vivo Neurotoolsmentioning

confidence: 99%

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Microelectromechanical Systems-Based Neurotools for Non-Invasive Ultrasound Brain Stimulation

Lee

2019

Chronobiol Med

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While the number of people suffering from brain disorders continues to increase in the modern aging society, it is still a challenge to develop effective treatments for many of these diseases. For example, the risk of Alzheimer' s disease (AD), an age-dependent disorder, doubles every five years after the age of 65. However, there is still no medication to treat AD. While pharmaceutical means offers the highest patient compliance, it is difficult to discover an effective drug for brain disorders because of the existence of the brain-blood barrier (BBB) within the brain capillary endothelia [1]. BBB, a tight junction that exists between the blood vessel and extracellular space of the brain, allows passage of only a fraction of small-molecule drugs. In addition to this physical limitation, the pharmacological approach suffers from drug resistance, sideeffects, tolerance, and dependence, which further complicates the

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Noninvasive Ultrasonic Neuromodulation in Freely Moving Mice

Cited by 69 publications

References 47 publications

Miniature ultrasound ring array transducers for transcranial ultrasound neuromodulation of freely-moving small animals

Miniature ultrasound ring array transducers for transcranial ultrasound neuromodulation of freely-moving small animals

A Review of Electric Impedance Matching Techniques for Piezoelectric Sensors, Actuators and Transducers

Microelectromechanical Systems-Based Neurotools for Non-Invasive Ultrasound Brain Stimulation

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