FUNCTIONAL NEAR-INFRARED SPECTROSCOPY{BASED ASSESSMENT OF ATTENTION IMPAIRMENTS AFTER TRAUMATIC BRAIN INJURY

ANNA C. MERZAGORA; MARIA T. SCHULTHEIS; BANU ONARAL; MELTEM IZZETOGLU

doi:10.1142/s1793545811001551

[1] G. Strangman et al., "Functional neuroimaging and cognitive rehabilitation for people with traumatic brain injury," American J. Phys. Med. Rehab. 84(1), 62-75 (2005).

[2] H. G. Belanger et al., "Recent neuroimaging techniques in mild traumatic brain injury," J. Neuropsychiatry Clin. Neurosci. 19(1), 5-20 (2007).

[3] J. G. Dubroff, A. Newberg, "Neuroimaging of traumatic brain injury," Seminars Neurol. 28(4), 548-557 (2008).

[4] R. M. Ruff et al., "Selected cases of poor outcome following a minor brain trauma: Comparing neuropsychological and positron emission tomography assessment," Brain Injury 8(4), 297-308 (1994).

[5] M. S. Humayun et al., "Local cerebral glucose abnormalities in mild closed head injured patients with cognitive impairments," Nuclear Med. Commun., 10(5), 335-344 (1989).

[6] R. S. Scheibel et al., "Altered brain activation during cognitive control in patients with moderate to severe traumatic brain injury," Neurorehab. Neural Rep. 21(1), 36-45 (2007).

[7] R. S. Scheibel et al., "Effects of severity of traumatic brain injury and brain reserve on cognitive-control related brain activation," J. Neurotrauma 26(9), 1447-1461 (2009).

[8] J. H. Ricker, F.G. Hillary, J. DeLuca, "Functionally activated brain imaging (O-15 PET and fMRI) in the study of learning and memory after traumatic brain injury," J. Head Trauma Rehab. 16(2), 191-205 (2001).

[9] S. H. A. Chen et al., "A study of persistent postconcussion symptoms in mild head trauma using positron emission tomography," J Neurol. Neurosurg. Psych. 74(3), 326-332 (2003).

[10] B. Levine et al., "Functional reorganisation of memory after traumatic brain injury: A study with H2150 positron emission tomography," J. Neurol. Neurosurg. Psych. 73(2), 173-181 (2002).

[11] J. K. Chen et al., "Functional abnormalities in symptomatic concussed athletes: An fMRI study," NeuroImage 22(1), 68-82 (2004).

[12] C. Christodoulou et al., "Functional magnetic resonance imaging of working memory impairment after traumatic brain injury," J Neurol. Neurosurg. Psych. 71(2), 161-168 (2001).

[13] T. W. McAllister et al., "Differential working memory load effects after mild traumatic brain injury," NeuroImage 14(5), 1004-1012 (2001).

[14] M. R. Newsome et al., "Working memory brain activation following severe traumatic brain injury," Cortex 43(1), 95-111 (2007).

[15] K. C. Russell et al., "A functional magnetic resonance imaging investigation of episodic memory after traumatic brain injury," J. Clin. Exp. Neuropsychol. 1-10 (2011).

[16] B. S. Kirkby et al., "Cognitive activation during PET: A case study of monozygotic twins discordant for closed head injury," Neuropsychologia 34(7), 689-697 (1996).

[17] W. J. Lombardi et al., "Wisconsin Card Sorting Test performance following head injury: Dorsolateral fronto-striatal circuit activity predicts perseveration," J. Clin. Exp. Neuropsychol. 21(1), 2-16 (1999).

[18] A. Soeda et al., "Cognitive impairment after traumatic brain injury: A functional magnetic resonance imaging study using the Stroop task," Neuroradiol. 47(7), 501-506 (2005).

[19] Y. H. Kim et al., "Plastic changes of motor network after constraint-induced movement therapy," Yonsei Med. J. 45(2), 241-246 (2004).

[20] G. E. Strangman et al., "Prediction of memory rehabilitation outcomes in traumatic brain injury by using functional magnetic resonance imaging," Arch. Phys. Med. Rehab. 89(5), 974-981 (2008).

[21] H. S. Levin, A. L. Benton, R. G. Grossman, Neurobehavioral Consequences of Closed Head Injury, Oxford University Press, New York (NY), 1982.

[22] T. W. Langfitt et al., "Computerized tomography, magnetic resonance imaging, and positron emission tomography in the study of brain trauma. Preliminary observations," J. Neurosurg. 64(5), 760-767 (1986).

[23] H. E. Egeth and S. Yantis, "Visual attention: Control, representation, and time course," Annual Rev. Psychol. 48(1), 269-297 (1997).

[24] L. Pessoa, S. Kastner, L.G.Ungerleider, "Neuroimaging studies of attention: From modulation of sensory processing to top-down control," J. Neurosci. 23(10), 3990-3998 (2003).

[25] R. Cabeza, L. Nyberg, "Imaging cognition II: An empirical review of 275 PET and fMRI studies," J. Cognitive Neurosci. 12(1), 1-47 (2000).

[26] J. T. Coull, "Neural correlates of attention and arousal: Insights from electrophysiology, functional neuroimaging and psychopharmacology," Progress Neurobiol. 55(4), 343-361 (1998).

[27] G. McCarthy et al., "Infrequent events transiently activate human prefrontal and parietal cortex as measured by functional MRI," J. Neurophysiol. 77(3), 1630-1634 (1997).

[28] M. Butti et al., "Combining near infrared spectroscopy and functional MRI during continuous performance test in healthy subjects," in 28th Annual International Conference of the IEEE EMBS, New York (NY), pp. 1944-1947, 2006.

[29] K. Izzetoglu et al., "NIR spectroscopy measurements of cognitive load elicited by GKT and target categorization," 36th Hawaii International Conference on System Sciences, the Augmented Cognition and Human-Robot Interaction, p. 6, 2003.

[30] R. P. Kennan et al., "Simultaneous recording of event-related auditory oddball response using transcranial near infrared optical topography and surface EEG," NeuroImage 16(3 Pt 1), 587-592 (2002).

[31] B. C. McDonald, L. A. Flashman, A. J. Saykin, "Executive dysfunction following traumatic brain injury: Neural substrates and treatment strategies," Neurorehab. 17(4), 333-344 (2002).

[32] C. Harrison-Felix et al., Descriptive Findings from the Traumatic Brain Injury Model Systems National Database, pp. 1-14, 1996.

[33] D. A. Wechsler, Wechsler Adult Intelligence Scale-III, New York (NY), Psychological Corporation, 1997.

[34] C. K. Conners, J. L. Jett, ADHD in Adults and Children: The Latest Assessment and Treatment Strategies, Kansas City (MO): Compact Clinicals, 1999.

[35] B. Chance et al., "A novel method for fast imaging of brain function, non-invasively, with light," Opt. Exp. 2(10), 411-423 (1998).

[36] M. Izzetoglu et al., "Functional near-infrared neuroimaging," IEEE Transact. Neural Syst. Rehab. Eng. 2(2), 153-159 (2005).

[37] M. Izzetoglu et al., "Functional brain imaging using near-infrared technology," IEEE Eng. Med. Biol. Magazine 26(4), 38-46 (2007).

[38] D. T. Delpy et al., "Estimation of optical pathlength through tissue from direct time of flight measurement," Phys. Med. Biol. 33(12), 1433-1442 (1988).

[39] T. Manly et al., "Enhancing the sensitivity of a sustained attention task to frontal damage: Convergent clinical and functional imaging evidence," Neurocase 9(4), 340-349 (2003).

[40] M. Rios, J. A. Perianez, J. M. Munoz-Cespedes, "Attentional control and slowness of information processing after severe traumatic brain injury," Brain Injury 18(3), 257-272 (2004).

[41] R. M. Ruff et al., "Attentional and informationprocessing deficits in head-injured and schizophrenic- patients," J. Clin. Exp. Neuropsychol. 7(6), 645-646 (1985).

[42] S. N. Niogi et al., "Structural dissociation of attentional control and memory in adults with and without mild traumatic brain injury," Brain 131(Pt 12), 3209-3221 (2008).

[43] B. A. Ardekani et al., "Functional magnetic resonance imaging of brain activity in the visual oddball task," Brain Research, Cognitive Brain Research, 14(3), 347-356 (2002).

[44] K. D. Alloway, T. C. Pritchard, Medical Neuroscience, 2nd edn., Hayes Barton Press: NC, Rayleigh, 2007.

[45] D. T. Stuss et al., "Reaction time after head injury: Fatigue, divided and focused attention, and consistency of performance," J. Neurol. Neurosurg. Psych. 52(6), 742-748 (1989).

[46] J. Whyte et al., "Sustained arousal and attention after traumatic brain injury," Neuropsychologia 33(7), 797-813 (1995).