| Literature DB >> 31222480 |
Manqing Wang1, Qingling Xia1, Fei Peng1, Bin Jiang1, Lin Chen1,2, Xiaoying Wu1,3, Xiaolin Zheng1,2, Xing Wang1,2,3, Tian Tian4, Wensheng Hou5,6,7.
Abstract
The post-stimulation response of neural activities plays an important role to evaluate the effectiveness and safety of neural modulation techniques. Previous studies have established the capability of infrared neural modulation (INM) on neural firing regulation in the central nervous system (CNS); however, the dynamic neural activity after the laser offset has not been well characterized yet. We applied 980-nm infrared diode laser light to irradiate the primary motor cortex of rats, and tungsten electrode was inserted to record the single-unit activity of neurons at the depth of 800-1000 μm (layer V of primary motor cortex). The neural activities were assessed through the change of neural firing rate and firing pattern pre- and post-stimulation with various radiant exposures. The results showed that the 980-nm laser could modulate the firing properties of neurons in the deep layer of the cortex. More neurons with post-stimulation response (78% vs. 83%) were observed at higher stimulation intensity (0.803 J/cm2 vs. 1.071 J/cm2, respectively). The change of firing rate also increased with radiant exposures increasing, and the response lasted up to 4.5 s at 1.071 J/cm2, which was significantly longer than the theoretical thermal relaxation time. Moreover, the increasing Fano factors indicated the irregularity firing pattern of post-stimulation response. Our results confirmed that neural activity maintained a prolonged post-stimulation response after INM, which may provide necessary measurable data for optimization of INM applications in CNS.Entities:
Keywords: Infrared neural stimulation; Post-stimulation response; Primary motor cortex; Short-wavelength infrared
Mesh:
Year: 2019 PMID: 31222480 DOI: 10.1007/s10103-019-02826-0
Source DB: PubMed Journal: Lasers Med Sci ISSN: 0268-8921 Impact factor: 3.161