BACKGROUND AND PURPOSE: Children born preterm are at risk for adverse outcome, including visual impairment. We examined the relationship between neonatal DTI and sVEP in children born preterm to determine whether visual outcomes are related to early measurements of brain microstructure. MATERIALS AND METHODS: Subjects were born at <34 weeks gestation and imaged before term-equivalent age. DTI fiber tracking was used to delineate the optic radiations and measure tract-specific average FA, D(av), and parallel and transverse diffusivity. Visual-evoked response amplitudes were measured as a function of spatial frequency, contrast, and vernier offset size with sVEP at 6-20 months after birth. The association between DTI and sVEP was assessed by using the Spearman correlation coefficient and linear regression for repeated measures. RESULTS: Nine children with 15 scans were included. The peak response amplitudes for spatial frequency sweeps were associated with increasing FA and decreasing D(av) and transverse diffusivity (P ≤ .006) but not with parallel diffusivity (P = 1). There was only modest association with the swept contrast condition and no detectable association with the vernier offset sweeps. CONCLUSIONS: Microstructure of the optic radiations measured shortly after birth is associated with quantitatively measured responses elicited by moderate-to-high contrast spatiotemporal gratings in infancy. These findings are in keeping with studies showing a relationship between brain microstructure and function. While the clinical impact is not known, quantitative neuroimaging of white matter may ultimately be important for predicting outcome in preterm neonates.
BACKGROUND AND PURPOSE:Children born preterm are at risk for adverse outcome, including visual impairment. We examined the relationship between neonatal DTI and sVEP in children born preterm to determine whether visual outcomes are related to early measurements of brain microstructure. MATERIALS AND METHODS: Subjects were born at <34 weeks gestation and imaged before term-equivalent age. DTI fiber tracking was used to delineate the optic radiations and measure tract-specific average FA, D(av), and parallel and transverse diffusivity. Visual-evoked response amplitudes were measured as a function of spatial frequency, contrast, and vernier offset size with sVEP at 6-20 months after birth. The association between DTI and sVEP was assessed by using the Spearman correlation coefficient and linear regression for repeated measures. RESULTS: Nine children with 15 scans were included. The peak response amplitudes for spatial frequency sweeps were associated with increasing FA and decreasing D(av) and transverse diffusivity (P ≤ .006) but not with parallel diffusivity (P = 1). There was only modest association with the swept contrast condition and no detectable association with the vernier offset sweeps. CONCLUSIONS: Microstructure of the optic radiations measured shortly after birth is associated with quantitatively measured responses elicited by moderate-to-high contrast spatiotemporal gratings in infancy. These findings are in keeping with studies showing a relationship between brain microstructure and function. While the clinical impact is not known, quantitative neuroimaging of white matter may ultimately be important for predicting outcome in preterm neonates.
Authors: D Prayer; A J Barkovich; D A Kirschner; L M Prayer; T P Roberts; J Kucharczyk; M E Moseley Journal: AJNR Am J Neuroradiol Date: 2001-09 Impact factor: 3.825
Authors: J Vernon Odom; Michael Bach; Colin Barber; Mitchell Brigell; Michael F Marmor; Alma Patrizia Tormene; Graham E Holder Journal: Doc Ophthalmol Date: 2004-03 Impact factor: 2.379
Authors: Steven P Miller; Camilla Ceppi Cozzio; Ruth B Goldstein; Donna M Ferriero; J Colin Partridge; Daniel B Vigneron; A James Barkovich Journal: AJNR Am J Neuroradiol Date: 2003-09 Impact factor: 3.825
Authors: Y Arzoumanian; M Mirmiran; P D Barnes; K Woolley; R L Ariagno; M E Moseley; B E Fleisher; S W Atlas Journal: AJNR Am J Neuroradiol Date: 2003-09 Impact factor: 3.825
Authors: J I Berman; H C Glass; S P Miller; P Mukherjee; D M Ferriero; A J Barkovich; D B Vigneron; R G Henry Journal: AJNR Am J Neuroradiol Date: 2008-10-02 Impact factor: 3.825
Authors: Savannah C Partridge; Pratik Mukherjee; Roland G Henry; Steven P Miller; Jeffrey I Berman; Hua Jin; Ying Lu; Orit A Glenn; Donna M Ferriero; A James Barkovich; Daniel B Vigneron Journal: Neuroimage Date: 2004-07 Impact factor: 6.556
Authors: Andrea L Murray; Deanne K Thompson; Leona Pascoe; Alexander Leemans; Terrie E Inder; Lex W Doyle; Jacqueline F I Anderson; Peter J Anderson Journal: Neuroimage Date: 2015-08-28 Impact factor: 6.556
Authors: Rafael Ceschin; Jessica L Wisnowski; Lisa B Paquette; Marvin D Nelson; Stefan Blüml; Ashok Panigrahy Journal: Neuroimage Clin Date: 2015-06-04 Impact factor: 4.881
Authors: Deanne K Thompson; Dolly Thai; Claire E Kelly; Alexander Leemans; Jacques-Donald Tournier; Michael J Kean; Katherine J Lee; Terrie E Inder; Lex W Doyle; Peter J Anderson; Rodney W Hunt Journal: Neuroimage Clin Date: 2013-11-28 Impact factor: 4.881
Authors: Claire E Kelly; Jeanie L Y Cheong; Carly Molloy; Peter J Anderson; Katherine J Lee; Alice C Burnett; Alan Connelly; Lex W Doyle; Deanne K Thompson Journal: PLoS One Date: 2014-03-24 Impact factor: 3.240