[1] V. Heiskanen, M. R. Hamblin,flPhotobiomodulation: Lasers vs light emitting diodes?" Photochem. Photobiol. Sci. (2018).
[2] M. A. Hadis, S. A. Zainal et al., "The dark art of light measurement: accurate radiometry for lowlevel light therapy," Lasers Med. Sci. 31(4), 789– 809 (2016).
[3] J. D. Batista, D. Zanetta-Barbosa et al., "Effect of low-level laser therapy on repair of the bone compromised by radiotherapy," Lasers Med. Sci. 29(6):1913 (2014).
[4] V. Spera, T. Sitnikova et al., "Transcranial nearinfrared light: dose-dependent effects on EEG oscillations but not cerebral blood flow," (2019). https://doi.org/10.1101/837591.
[5] R. Zein, W. Setting, M. R. Hamblin, "Review of light parameters and photobiomodulation efficacy: dive into complexity," J. Biomed. Opt. 23 (12):120901.1–120901.17 (2018).
[6] S. Belletti, J. Uggeri et al., "Effects of 915 nm GaAs diode laser on mitochondria of human dermal fibroblasts: analysis with confocal microscopy," Lasers Med. Sci. 30(1):375–381 (2014).
[7] M. T. Delpy and M. Cope, "Quantification in tissue near-infrared spectroscopy," Phil. Trans. R. Soc. Lond. B 352:649–659 (1997).
[8] Y. Wang et al., "Photobiomodulation (blue and green light) encourages osteoblastic-differentiation of human adipose-derived stem cells: role of intracellular calcium and light-gated ion channels," Sci. Rep. 6:33719 (2016).
[9] N. J. Blanco, W. T. Maddox et al., "Improving executive function using transcranial infrared laser stimulation," J. Neuropsychol. 11(1): (2017).
[10] T. A. Henderson, L. D. Morries et al., "Multi-watt near-infrared phototherapy for the treatment of comorbid depression: An open-label single-arm study," Front. Psychiatry 8:187 (2017).
[11] P. A. Lapchak, P. D. Boitano et al., "Transcranial near-infrared laser transmission (NILT) profiles (800 nm): Systematic comparison in four common research species," PLOS ONE 10(6): e0127580 (2015).
[12] R. Zomorrodi et al., "Pulsed near infrared transcranial and intranasal photobiomodulation signifi- cantly modulates neural oscillations: a pilot exploratory study," Sci. Rep. 9(1): (2019).
[13] N. J. Blanco, W. T. Maddox, F. Gonzalez-Lima, "Improving executive function using transcranial infrared laser stimulation," J. Neuropsychol. 11 (1):14–25 (2017).
[14] S. G. Disner, C. G. Beevers, F. Gonzalez-Lima, "Transcranial laser stimulation as neuroenhancement for attention bias modification in adults with elevated depression symptoms," Brain Stimul. 9 (5):780–787 (2016).
[15] Q. Wu et al., "Low-level laser therapy for closedhead traumatic brain injury in mice: effect of different wavelengths," Lasers Surg. Med. 44:218–226 (2012).
[16] T. A. Henderson, M. Larry et al., "Treatments for traumatic brain injury with emphasis on transcranial near-infrared laser phototherapy," Neuropsych. Dis. Treat. 2015(11):2159–2175 (2015).
[17] M. A. Naeser, P. I. Martin et al., "Transcranial, red/ near-infrared light-emitting diode therapy to improve cognition in chronic traumatic brain injury," Photomed. Laser Surg. 34(12):610–626 (2016).
[18] F. Salehpour et al., "Transcranial low-level laser therapy improves brain mitochondrial function and cognitive impairment in D-galactose-induced aging mice," Neurobiol. Aging 58: 140–150 (2017).
[19] J. T. Hashmi et al., "Effect of pulsing in low-level light therapy," Lasers Surg. Med. 42(6): 450–466 (2010).
[20] Z. Cao, W. Ding et al., "Effects of repetitive SSVEPs on EEG complexity using multiscale inherent fuzzy entropy", Neurocomputing 8(091): (2019).
[21] C.-G. B_enar et al., "Differences in MEG and EEG power-law scaling explained by a coupling between spatial coherence and frequency: a simulation study," J. Comput. Neurosci. 47(1): (2019).
[22] J. J. Yong, D. Kim et al., "Towards a physiologybased measure of visual discomfort: brain activity measurement while viewing stereoscopic images with different screen disparities," Disp. Technol. 11 (9):730–743 (2015).
[23] E. A. Luschekina, V. S. Luschekin et al., "EEG spectral power in children with autistic spectrum disorders: Heterogeneity of the group," Human Physiol. 45(3):242–248 (2019).
[24] J. Xiang, R. Cao et al., "Emotion recognition based on the sample entropy of EEG," Bio-Med. Mater. Eng. 24(1):1185 (2014).
[25] T. I. Karu et al., "Exact action spectra for cellular responses relevant to phototherapy," Photomed. Laser Surg. 23(4):355–361 (2005).
[26] L. Ingber, M. Pappalepore et al., "Electroencephalographic field influence on calcium momentum waves," J. Theor. Biol. 343:138–153 (2014).
[27] A. Jahan, M. A. Nazari et al., "Transcranial nearinfrared photobiomodulation could modulate brain electrophysiological features and attentional performance in healthy young adults," Lasers Med. Sci. 4:1193–1200 (2019).
[28] R. Zomorrodi et al., "Modulation of neural oscillation power spetral density with transcranial photobiomodulation," Brain Stimul. 12(2):457–458 (2019).
[29] C. Chen et al., "Assessment visual fatigue of watching 3DTV using EEG power spectral parameters," Displays 35(5):266–272 (2014).
[30] W. Klimesch, "EEG-alpha rhythms and memory processes," Int. J. Psychophysiol. 26(1–3):319–340 (1997).
[31] R. J. Compton et al., "The wandering mind oscillates: EEG alpha power is enhanced during moments of mind-wandering," Cogn. Affect. Behav. Neurosci. 19(4): (2019).
[32] Md. Asadur Rahman et al., "EEG based brain alertness monitoring by statistical and artificial neural network approach," Int. J. Adv. Comput. Sci. Appl. 10(1): (2019).
[33] T. A. Henderson et al., "Multi-watt near-infrared phototherapy for the treatment of comorbid depression: An open-label single-arm study," Front. Psychiatry 8:187 (2017).
[34] F. Grover, J. Weston et al., "Acute effects of near infrared light therapy on brain state in healthy subjects as quantified by qEEG measures," Photomed. Laser Surg. 35(3): 136–141 (2017).