Effects of near-infrared low-level laser (NIR LLL) on brain excitability have been seldom investigated. A few studies carried out so far showed that following several minutes of transcranial NIR LLL illumination, the output of the primary motor cortex area in humans, measured by transcranial magnetic stimulation (TMS), is inhibited for at least half an hour. The effect seems to be dose dependent. Given that NIR LLL is known to boost metabolic activity in the illuminated neurons, the results may suggest that this allows for more efficient functioning of the cell membrane potential maintenance mechanisms which are then able to resist more effectively external perturbations (such as TMS). Alternatively, it may be that, due to the morphological complexity of the cerebral cortex coupled with the size of the area illuminated by a laser beam, transcranial LLL induces activation in a large population of the cortical cells of various functional features. Because of their abundance in the most s...uperficial cortical layers, inhibitory interneurons may be the principal recipients of the NIR LLL effects thus causing an inhibition of the output from more deeply-seated, large pyramidal cells. Further investigations are needed to better understand these effects.
Keywords:
ATP / Cell metabolism / Inhibition / Membrane potential / Near-infrared light / Neuronal excitability / Transcranial magnetic stimulation
Source:
Photobiomodulation in the Brain: Low-Level Laser (Light) Therapy in Neurology & Neuroscience, 2019, 233-240
TY - CHAP
AU - Konstantinović, Ljubica
AU - Filipović, Saša
PY - 2019
UR - http://rimi.imi.bg.ac.rs/handle/123456789/972
AB - Effects of near-infrared low-level laser (NIR LLL) on brain excitability have been seldom investigated. A few studies carried out so far showed that following several minutes of transcranial NIR LLL illumination, the output of the primary motor cortex area in humans, measured by transcranial magnetic stimulation (TMS), is inhibited for at least half an hour. The effect seems to be dose dependent. Given that NIR LLL is known to boost metabolic activity in the illuminated neurons, the results may suggest that this allows for more efficient functioning of the cell membrane potential maintenance mechanisms which are then able to resist more effectively external perturbations (such as TMS). Alternatively, it may be that, due to the morphological complexity of the cerebral cortex coupled with the size of the area illuminated by a laser beam, transcranial LLL induces activation in a large population of the cortical cells of various functional features. Because of their abundance in the most superficial cortical layers, inhibitory interneurons may be the principal recipients of the NIR LLL effects thus causing an inhibition of the output from more deeply-seated, large pyramidal cells. Further investigations are needed to better understand these effects.
T2 - Photobiomodulation in the Brain: Low-Level Laser (Light) Therapy in Neurology & Neuroscience
T1 - Effects of near-infrared low-level laser stimulation on neuronal excitability
EP - 240
SP - 233
DO - 10.1016/B978-0-12-815305-5.00018-X
UR - conv_5076
ER -
@inbook{
author = "Konstantinović, Ljubica and Filipović, Saša",
year = "2019",
abstract = "Effects of near-infrared low-level laser (NIR LLL) on brain excitability have been seldom investigated. A few studies carried out so far showed that following several minutes of transcranial NIR LLL illumination, the output of the primary motor cortex area in humans, measured by transcranial magnetic stimulation (TMS), is inhibited for at least half an hour. The effect seems to be dose dependent. Given that NIR LLL is known to boost metabolic activity in the illuminated neurons, the results may suggest that this allows for more efficient functioning of the cell membrane potential maintenance mechanisms which are then able to resist more effectively external perturbations (such as TMS). Alternatively, it may be that, due to the morphological complexity of the cerebral cortex coupled with the size of the area illuminated by a laser beam, transcranial LLL induces activation in a large population of the cortical cells of various functional features. Because of their abundance in the most superficial cortical layers, inhibitory interneurons may be the principal recipients of the NIR LLL effects thus causing an inhibition of the output from more deeply-seated, large pyramidal cells. Further investigations are needed to better understand these effects.",
journal = "Photobiomodulation in the Brain: Low-Level Laser (Light) Therapy in Neurology & Neuroscience",
booktitle = "Effects of near-infrared low-level laser stimulation on neuronal excitability",
pages = "240-233",
doi = "10.1016/B978-0-12-815305-5.00018-X",
url = "conv_5076"
}
Konstantinović, L.,& Filipović, S.. (2019). Effects of near-infrared low-level laser stimulation on neuronal excitability. in Photobiomodulation in the Brain: Low-Level Laser (Light) Therapy in Neurology & Neuroscience, 233-240.
https://doi.org/10.1016/B978-0-12-815305-5.00018-X
conv_5076
Konstantinović L, Filipović S. Effects of near-infrared low-level laser stimulation on neuronal excitability. in Photobiomodulation in the Brain: Low-Level Laser (Light) Therapy in Neurology & Neuroscience. 2019;:233-240.
doi:10.1016/B978-0-12-815305-5.00018-X
conv_5076 .
Konstantinović, Ljubica, Filipović, Saša, "Effects of near-infrared low-level laser stimulation on neuronal excitability" in Photobiomodulation in the Brain: Low-Level Laser (Light) Therapy in Neurology & Neuroscience (2019):233-240,
https://doi.org/10.1016/B978-0-12-815305-5.00018-X .,
conv_5076 .
