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Progressive Thinning of Visual Cortex in Primary Open-Angle Glaucoma of Varying Severity

  • Longhua Yu ,

    Contributed equally to this work with: Longhua Yu, Liqi Xie

    Affiliations Department of Radiology, Southwest Hospital, Third Military Medical University, Chongqing, China, Department of Radiology, 401st Hospital of the People’s Liberation Army, Qingdao, Shandong, China

  • Liqi Xie ,

    Contributed equally to this work with: Longhua Yu, Liqi Xie

    Affiliation Department of Radiology, 401st Hospital of the People’s Liberation Army, Qingdao, Shandong, China

  • Chao Dai,

    Affiliation Ophthalmology research center, Southwest Hospital, Third Military Medical University, Chongqing, China

  • Bing Xie,

    Affiliation Department of Radiology, Southwest Hospital, Third Military Medical University, Chongqing, China

  • Minglong Liang,

    Affiliation Department of Radiology, Southwest Hospital, Third Military Medical University, Chongqing, China

  • Lu Zhao,

    Affiliation McConnell Brain Imaging Centre, Montreal Neurological Institute, McGill University, Montreal, Quebec, Canada

  • Xuntao Yin ,

    xuntaoyin@gmail.com (XY); wangjian811@gmail.com (JW)

    Affiliations Department of Radiology, Southwest Hospital, Third Military Medical University, Chongqing, China, McConnell Brain Imaging Centre, Montreal Neurological Institute, McGill University, Montreal, Quebec, Canada

  • Jian Wang

    xuntaoyin@gmail.com (XY); wangjian811@gmail.com (JW)

    Affiliation Department of Radiology, Southwest Hospital, Third Military Medical University, Chongqing, China

Abstract

The aim of this study was to investigate possible changes of cortical thickness in the visual cortex in primary open-angle glaucoma (POAG) of varying severity. Twenty normal controls (NC), 20 mild (MP) and 17 severe (SP) POAG patients were recruited and scanned using magnetic resonance imaging. Cortical thickness analyses with regions of interest (V1, V2, ventral V3, V4 and V5/MT+) were used to assess the cortical changes among the three groups. Furthermore, the associations of cortical thickness with retinal nerve fiber layer (RNFL) thickness and mean deviation of visual field were analyzed. Compared with the NC group, decreased cortical thickness was detected in the bilateral V5/MT+ areas in the MP group and the left V1, bilateral V2 and V5/MT+ areas in the SP group. Cortical thinning of the bilateral V2 areas was detected in the SP group compared with the MP group. In addition, cortical thinning of these visual areas was related to the ophthalmologic measurements. In conclusion, POAG patients exhibit cortical thinning in the bilateral V5/MT+ in the early stage of disease. The cortical degeneration in visual areas is discrepant with disease progressing and the dorsal pathway might be selectively damaged in POAG. Therefore, the cortical thinning of these visual areas may play a key role in the progression of POAG and can serve as a novel biomarker for accurately evaluating the severity of POAG.

Introduction

Primary open-angle glaucoma (POAG) is a progressive optic neuropathy and is characterized by irreversible retinal ganglion cells (RGCs) and optic nerve fibers loss [1], resulting in corresponding psychophysical abnormalities, such as visual field loss. Although in the retina glaucoma selectively affects the layer of RGCs, primate experiments and human postmortem histologic studies have revealed that glaucomatous damage extends from the RGCs to the lateral geniculate nucleus (LGN) and even to the primary visual cortex (V1, striate cortex) [26]. These studies indicated that glaucoma is a complex disorder in which the whole visual pathway may be involved.

Recently, several voxel-based morphometry (VBM) studies on magnetic resonance imaging (MRI) data have examined the disruption of brain gray matter (GM) in patients with POAG. These studies have demonstrated GM atrophy in the V1 and the second major visual area (V2) [710], indicating that signs of neurodegeneration in visual cortex encompass upstream parts of the higher visual areas (extrastriate cortex). However, the VBM technique is limited by the fact that it conflates information about morphology, size and position [11]. Surface-based morphometry (SBM) is an alternative approach that enables independent measurements of cortical thickness across the continuous cortical surface [12,13], which may be likely to yield more precise information regarding the underlying disease mechanisms. More recently, cortical thinning [14,15] in BA17 (V1), BA18 (V2) and BA19 was shown in the POAG patients by using the SBM approach. Nevertheless, the majority of MRI-based studies focused on GM changes in the advanced/severe stage of POAG [7,9,10]. Because visual impairment from POAG could be irreversible, early detection is vital [16]. Our recent whole-brain studies [8,15] failed to detect the GM changes in the early stage of POAG, which might be attributed to the small sample size.

Additionally, the majority of the whole-brain VBM and SBM studies were only performed on the voxel/vertex and did not correspond to specific brain sulco-gyral structures or specific brain functional regions. That may cause difficulties or inconsistences when comparing the results with other similar studies. For example, the V5/MT+ (middle temporal gyrus), which plays a significant role in motion perception [1719], has been reported to be decreased [8,15], increased [10], or unchanged [9] in the GM by the whole-brain cortical studies. Therefore, it is necessary to assess the changes of cortical thickness in different visual areas separately, which may lead to not only a better understanding of the disease progression but an update on biomarkers. Using the regions of interest (ROIs)-based approach, Boucard and colleagues [7] found that visual field defects caused by POAG were associated with reduction in GM density in the V1. In another ROIs study, Bogorodzki et al. [14] reported that the cortical thickness of the BA19 was significantly decreased in the left and right hemispheres. However, the two study either only evaluated the GM of the V1 or only focused on the end-stage of the POAG. The objective of the present study was to investigate possible alternations of the visual cortex in patients with varying degrees of POAG using the ROI-based cortical thickness analysis. A well-validated and highly accurate surface-based method [13] was used to examine cortical thickness of the V1, V2, V3, V4 and V5/MT+ areas. Additionally, the correlations between the cortical thickness in these visual areas and clinical measurements were also investigated.

Materials and Methods

Ethics Statement

This study was approved by the Human Research Ethics Committees of the Third Military Medical University and was conducted in accordance with the Declaration of Helsinki. Written informed consent was obtained from all of the participants.

Subjects

Thirty-seven patients with first-diagnosed bilateral POAG were enrolled in this study. The following diagnostic criteria of the American Academy of Ophthalmology was used to identify POAG: intraocular pressure ≥ 21 mmHg, a glaucomatous optic disc and visual field abnormalities, and a nonoccludable anterior chamber angle without the characteristics of either congenital or secondary glaucoma. The exclusion criterion was a recorded diagnosis of any other ocular, neurological, or psychiatric disorder(s).

The normal control (NC) group was comprised of 20 age-, gender-, and education- matched healthy subjects. All the control subjects underwent a comprehensive ophthalmologic examination to exclude glaucoma and other eye diseases. All of the participants were right-handed and individuals with ophthalmic edema, inflammation or trauma, a history of amblyopia or ophthalmic surgery, age-related macular degeneration, or detectable brain abnormalities on MRI scans were excluded from the study.

Retinal Nerve Fiber Layer (RNFL) Thickness and Visual Field Examination

RNFL thickness was measured quantitatively using Topcon 3D optical coherence tomography (OCT-1000, Topcon Corporation, Tokyo, Japan). Visual field examinations were performed using the 30–2 program of the Humphrey Visual Field Analyzer (Carl Zeiss Meditec, Dublin, Calif). The steps were described in detail in our previous article [15]. The universal RNFL thickness and mean deviation (MD) of visual field were recorded.

Because the visual inputs from the ipsilateral temporal hemiretina and the contralateral nasal hemiretina project to the ipsilateral hemisphere, the mean clinical measurements (RNFL thickness and MD of visual field) for both eyes [15,20] were also recorded for statistical analyses.

Mild and Severe Patient Groups

Based on the Hodapp-Anderson-Parrish system [21], the patients were split into two groups (Table 1). The severe patient (SP) group (17 patients) was defined as MD scores < -6 dB in the better performing eye. This criterion includes the moderate, advanced and severe stages of the disease (stages 2–4). The mild patients (MP) group (20 patients) was defined as early stage disease (stage 1, -6 ≤ MD < 0 dB) in both eyes. Patients in either stage 0 (MD > 0 dB) or stage 5 (unable to perform Humphrey visual fields in the “worst eye”) were not enrolled in this study.

Structural MRI Acquisition

The MRI experiment was performed using a 3-Tesla scanner (Magnetom Trio, Siemens, Erlangen, Germany) with an 8-channel phased-array head coil. The subjects were required to close their eyes and avoid any movement during the image acquisition. 3D high-resolution structural images were obtained using a T1-weighted magnetization prepared rapid acquisition gradient echo (MPRAGE) sequence. A sagittal continuous no-interval scan covering the whole brain was performed with the following parameters: repetition time, 1,830 ms; echo time, 4.43 ms; inversion time, 1,100 ms; flip angle, 9°; matrix, 256 × 256 mm2; 176 slices; and voxel size, 1.0 × 1.0 × 1.0 mm3.

MRI Data Processing

Cortical reconstruction and volumetric segmentation was performed with FreeSurfer (version 5.3.0, http://surfer.nmr.mgh.harvard.edu). The automated processing stream mainly included removal of non-brain tissue [22], Talairach transformation, segmentation of gray/white matter tissue [23], intensity normalization, topological correction of the cortical surface [24] and surface deformation to optimally place the tissue borders [25]. After creation of the cortical representations, the visual areas were parcellated based on existing atlases. The delineation of the V1 label was based on the study by Hinds et al. [26] and corresponded to Brodmann area (BA) 17 (Fig. 1B), and the V2 label was described by Fischl et al. [27] and corresponded to BA 18 (Fig. 1E). The delineation of the V5/MT+ label was based on the work of Malikovic et al. [28]. This V5/MT+ area was located close to the intersection of the anterior occipital and the inferior lateral occipital sulci in the region of the temporo-occipital junction (Fig. 1N). As the V3 and V4 templates are not available in FreeSurfer, we extracted the ventral V3 (V3v) and V4 using the Juelich histological atlas implemented in FSL (http://fsl.fmrib.ox.ac.uk/fsl/fslwiki/Atlases/Juelich). The templates were transformed into surface labels and manually corrected according to Rottschy’s description [29]. The V3v is buried deep in the collateral sulcus (Fig. 1H) and V4 is located on the lateral bank of this sulcus but also reaches the fusiform gyrus in the occipital section (Fig. 1K). The dorsal V3 was not delineated here because there are differing views regarding its anatomical location and additional subdivisions [30]. The labels were then registered to the surface of each subject using the spherical parameters of the cortical surface [31]. For each subject, the five visual areas were visually inspected for any inaccuracies in parcellation and manually corrected if necessary.

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Fig 1. Correlations between cortical thickness of the visual areas and ophthalmic examination indexes.

The labels of the V1 (B), V2 (E), V3v (H), V4 (K) and V5/MT+ (N) visual areas are only displayed on the left inflated surface. However, it should be noted that the average cortical thickness was computed for the homogeneous areas in bilateral hemispheres. RNFL, retinal nerve fiber layer thickness; MD, mean deviation of the visual field.

https://doi.org/10.1371/journal.pone.0121960.g001

Cortical thickness was calculated as the average of the distance from the white matter surface to the closest point on the pial surface and from that point back to the closest point on the white matter surface [25]. For each visual area, we computed the average cortical thickness across that area.

Statistical Analysis

Continuous variables were tested for normality using the Shapiro–Wilk test and visual inspection of histograms. Differences in the demographic and clinical measurements were assessed using analyses of variance (ANOVA), and the chi-square test was used for gender. Multiple analyses of covariance (MANCOVAs) were conducted to examine group differences in the cortical thickness results, using age and gender as covariates. A two-tailed p < 0.05 was considered statistically significant. Significant group effects were then further explored using Bonferroni post-hoc analyses (p < 0.05).

Finally, Spearman’s correlation analyses adjusted for age and gender were used to explore the associations between the mean clinical measurements (RNFL thickness and MD of visual field) for both eyes [15,21] and the mean cortical thickness of bilaterally homologous visual areas [32] across the whole patients. All of the statistical analyses were conducted using SPSS software (version 18.0, Chicago, USA).

Results

Demographic and Clinical Measurements

The demographic characteristics and clinical measurements are presented in Table 1. The three groups did not differ significantly with regard to age, gender or education. The clinical measurements of the SP group were significantly lower than those of the MP group (p < 0.001).

Cortical Thickness

Table 2 shows the Bonferroni-adjusted differences in cortical thickness among the three groups. Compared with the NC group, the SP group had significantly lower thickness in the left V1 area and bilateral V2 and V5/MT+ visual cortices, whereas the MP group only exhibited a significant reduction of cortical thickness in the V5/MT+ area. Although the thickness of these visual cortices was reduced in the SP group relative to the MP group, only the differences in the bilateral V2 regions were statistically significant. In contrast, there were no significant differences in cortical thickness of V3v and V4 among the three groups.

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Table 2. Comparison of cortical thickness among the NC, MP and SP groups.

https://doi.org/10.1371/journal.pone.0121960.t002

Correlations between Cortical Thickness and Clinical Measurements

The Spearman’s correlation analyses showed that the mean RNFL thickness in the POAG patients was positively correlated with cortical thickness in the V2 (Spearman correlation coefficient ρ = 0.38, p = 0.02) and V5/MT+ (ρ = 0.44, p = 0.006) regions (Fig. 1D and 1M). Additionally, the mean MD was also related to cortical thickness in the V1 (ρ = 0.34, p = 0.04), V2 (ρ = 0.42, p = 0.009) and V5/MT+ (ρ = 0.37, p = 0.03) areas (Fig. 1C, 1F and 1O). No significant correlations was found between V3v/V4 cortical thickness and ophthalmologic measurements.

Discussion

The present study examined the cortical thickness of the central visual areas in POAG patients. Compared with the NC group, decreased cortical thickness was detected in the bilateral V5/MT+ areas in the MP group and the left V1, bilateral V2 and V5/MT+ areas in the SP group. Additionally, cortical thinning of the bilateral V2 areas was detected in the SP group compared with the MP group. In addition, the thinning of visual cortex in POAG patients was significantly related to the deterioration of ophthalmologic measurements. These results indicated that the cortical thickness of specific visual areas could serve as biomarkers for the early diagnosis and judgment of progression in patients with POAG.

According to the cortical thickness analyses, cortical degeneration within the visual areas became progressively aggravated with the increasing severity of POAG. Consistent with the current findings, our recent vertex-based analysis across the whole brain revealed cortical thickness changes in the regions around the bilateral calcarine sulci [15]. In addition, several VBM studies have demonstrated a significant reduction in GM in the V1 and V2 areas [710], corresponding to the visual field defects caused by POAG [7,10]. However, the majority of these studies did not distinguish the differences of GM atrophy or functional defects among different stages of POAG, which is important to consider for understanding the progressive changes in the visual cortex. Besides, our previous studies also failed to pass the strict statistical correction for the multiple comparisons [8,15], which might be partly due to the heterogeneous changes of brain GM in POAG. In the present study, cortical thickness of the V1 and V2 areas did not change significantly in MP group but changed significantly in SP group, indicating that visual impairment is progressive and irreversible. Therefore, greater attention should be paid to prevention and early intervention for brain lesions in patients with POAG.

In POAG, the progressive reduction of thickness in the visual cortex may be attributed to the progressive loss of RGCs. Atrophy of the damaged parts of the retina likely propagates by means of transneuronal degeneration via the optic nerve towards the visual cortex, thereby provoking the subsequent degeneration of the visual cortex [33]. This sequence of events has been shown in both experimental animal models [34] and postmortem report [5]. In the present study, there was no significant alteration of the V1 area in the MP group, which may be explained by the fact that the majority of retinal inputs project to layer 4 of the V1 area. The two major visual pathways, magnocellular (M) and parvocellular (P) pathways, terminate primarily at layer 4Cα and layer 4A/4Cβ of the V1 cortex, respectively [35]. It is speculated that selective neurodegeneration may occur in layer 4 of the V1 area without extensively affecting the other five layers in the early stage of POAG. Because the six layers of the V1 area exist intracortical connections [36] and the death of neurons connected to the glaucomatous eye induces oxidative injury [37] and glial activation [34], the other five layers of the V1 area may be progressively disturbed as POAG worsens. Thus, cortical thickness in the V1 area exhibited a significant reduction in the advanced or severe stages of disease. Because the V2 area receives strong feedforward connections from the V1 area and has many properties in common with the V1 area, a similar mechanism of progressive neurodegeneration may also exist in the V2 area. Therefore, there was also no significant alteration in the cortical thickness of the V2 in the MP group.

The V2 degenerated rapidly while the V1 changed little when the disease deteriorated from mild to severe stage. A possibility may be that V2 neurons are modulated by more complex properties than V1, such as visual form [38,39] and motion processing [40,41], both of which are impaired in POAG patients [42,43]. Another possibility is that the topography in V2, which differs from the relatively orderly retinotopy of V1, is parcellated into functional modules which are locally retinotopic [44]. In addition, the size of V2 modules is greater than the orientation modules and blobs of V1, and the collection of hypercolumns for a point set spans the width of an entire stripe cycle in V2 (thin/pale/thick/pale) [44]. Taken together, more neurons and a larger area in V2 than V1 may be involved in the glaucomatous visual impairment with disease progression, and thus the cortical thickness of the V2 area was significantly reduced in the SP group.

Because visual impairment from POAG is aggravated progressively, early detection and diagnosis of glaucomatous disorders is vital [16]. In our previous studies, the mild patients (MP) group were defined as -10dB < MD < 0dB (Becker visual field stages) [8] or -12dB < MD < 0dB (including stages 1 and 2 in Hodapp-Anderson-Parrish system) [15] in both eyes. As more POAG patients were recruited, the MP group in the present study were redefined as -6 ≤ MD < 0 dB in both eyes, which is equal to stage 1 (early defect of visual field) in the Hodapp-Anderson-Parrish system [21], and the SP group were defined as MD scores < -6 dB (at least in stage 2) in the better performing eye. It is anticipated that the more stringent grading standard could help to reveal the earliest pathological features in POAG.

In the present study, we identified an alteration in cortical thickness of the V5/MT+ area in the early stage of POAG. The V5/MT+ area is located in the dorsal visual pathway and receives significant input from the M pathway [45]. Neuropathological examinations have revealed marked degenerative changes in the structures constituting this pathway, including RGCs [36], optic nerve fibers [46] and LGN [24]. In addition, neuronal activity in the V5/MT+ area play a key role in perception of visual motion [17,47]. Previous psychophysical studies have revealed disturbances in motion perception in patients with early POAG using either motion perimetry [48] or motion stimuli [49]. We therefore speculated that the degeneration of the V5/MT+ in early stage of disease might be interpreted as the absence of visual motion stimulation, as the absence of stimulation may result in changes in the cortical structure [50].

The pathology of glaucoma has been extensively studied at anterior visual pathway (M and P pathway) such as the retina and LGN. Most of these studies revealed a preferential damage to the M pathway [46,51,52] although a few of them supported a damage to the P pathway as well [2]. Recently, an autopsy study on a patient with advanced glaucoma found the degenerative changes in the brain involving the intracranial optic nerve, LGN and the V1 [5]. However, that study did not investigate the higher visual areas, such as the V3, V4 and V5/MT+ areas. The V3v and V4 areas locate in the ventral visual pathway, which mainly receive the visual inputs from the P pathway and play a significant role in processing color [53], form [54] and depth [55]. In this study, the cortical thickness in the V5/MT+ decreased significantly but there were no change in the V3v and V4 areas, indicating that the dorsal pathway may be selectively damaged in central visual system in POAG.

The significant positive correlations between cortical thickness of the visual areas and the ophthalmic measurements indicated that cortical thickness of the visual cortex in POAG patients varied consistently with RNFL and visual field damage. Previous studies have shown that diffusion parameters of optic nerves [56], optic tracts and optic radiations [21] correlated significantly with RNFL thickness in glaucoma. However, with regard to the visual cortex, the correlation between cortical thickness and the ophthalmic indexes has seldom been studied in human POAG. Our results provide new information about the neural basis of visual damage and support the use of cortical thickness analysis for studying patients with POAG. Thus, cortical thickness of visual areas may serve as a novel biomarker for determining POAG severity.

There are potential limitations that should be addressed. First, the sample size was relatively small, which reduces both statistical power and the ability to perform whole-brain analyses. Second, histological evidence of the observations cannot be provided because this study involved human subjects. As a result, our study could not verify whether layer 4 in the V1 is involved in the early stage of POAG. Future animal experiments and autopsies might resolve this problem. Third, because our study is cross-sectional in design, longitudinal studies should be employed to confirm our findings and to clarify the progression of the structural changes in visual areas in patients in the early stage of POAG. Finally, the current imaging study did not permit conclusions on the potential causal relationship between GM alternations in the visual cortex and ophthalmic lesions. Further investigations should be performed to explore the underlying molecular mechanisms.

Conclusion

This study provides direct in vivo evidence of the progressive thinning in the visual cortex in patients with POAG. The most significant novel finding is that cortical thickness of the bilateral V5/MT+ areas decreases in the early stage of POAG. Thus, it should be paid more attention on early prevention of cortical degeneration associated with eye diseases, which might improve the clinical outcome for patients with POAG. Another notable finding is that the dorsal pathway may be more preferentially damaged than the ventral visual pathway in central visual system. Additionally, the cortical degeneration in V1and V2 is discrepant when the disease deteriorated from mild to severe stage. Finally, we showed that the thickness of visual cortex correlated well with RNFL thickness and visual field examination findings in POAG patients. Taken together, our findings suggest that the thickness of visual cortex is helpful in detecting POAG pathology and could serve as an indicator of disease severity.

Author Contributions

Conceived and designed the experiments: LY LX JW. Performed the experiments: LY LX. Analyzed the data: LY LX CD BX ML XY JW. Contributed reagents/materials/analysis tools: LY LX CD BX ML LZ XY JW. Wrote the paper: LY LX CD BX LZ XY JW.

References

  1. 1. Leske MC (2007) Open-angle glaucoma—an epidemiologic overview. Ophthalmic Epidemiol 14: 166–172. pmid:17896292
  2. 2. Yucel YH, Zhang Q, Gupta N, Kaufman PL, Weinreb RN (2000) Loss of neurons in magnocellular and parvocellular layers of the lateral geniculate nucleus in glaucoma. Arch Ophthalmol 118: 378–384. pmid:10721961
  3. 3. Weber AJ, Chen H, Hubbard WC, Kaufman PL (2000) Experimental glaucoma and cell size, density, and number in the primate lateral geniculate nucleus. Invest Ophthalmol Vis Sci 41: 1370–1379. pmid:10798652
  4. 4. Yucel YH, Zhang Q, Weinreb RN, Kaufman PL, Gupta N (2001) Atrophy of relay neurons in magno- and parvocellular layers in the lateral geniculate nucleus in experimental glaucoma. Invest Ophthalmol Vis Sci 42: 3216–3222. pmid:11726625
  5. 5. Gupta N, Ang LC, Noel de Tilly L, Bidaisee L, Yucel YH (2006) Human glaucoma and neural degeneration in intracranial optic nerve, lateral geniculate nucleus, and visual cortex. Br J Ophthalmol 90: 674–678. pmid:16464969
  6. 6. Shimazawa M, Ito Y, Inokuchi Y, Yamanaka H, Nakanishi T, et al. (2012) An alteration in the lateral geniculate nucleus of experimental glaucoma monkeys: in vivo positron emission tomography imaging of glial activation. PLoS One 7: e30526. pmid:22299044
  7. 7. Boucard CC, Hernowo AT, Maguire RP, Jansonius NM, Roerdink JB, et al. (2009) Changes in cortical grey matter density associated with long-standing retinal visual field defects. Brain 132: 1898–1906. pmid:19467992
  8. 8. Li C, Cai P, Shi L, Lin Y, Zhang J, et al. (2012) Voxel-based morphometry of the visual-related cortex in primary open angle glaucoma. Curr Eye Res 37: 794–802. pmid:22631870
  9. 9. Zikou AK, Kitsos G, Tzarouchi LC, Astrakas L, Alexiou GA, et al. (2012) Voxel-based morphometry and diffusion tensor imaging of the optic pathway in primary open-angle glaucoma: a preliminary study. AJNR Am J Neuroradiol 33: 128–134. pmid:22116110
  10. 10. Chen WW, Wang N, Cai S, Fang Z, Yu M, et al. (2013) Structural Brain Abnormalities in Patients with Primary Open-Angle Glaucoma: A Study with 3T MR Imaging. Invest Ophthalmol Vis Sci 54: 545–554. pmid:23258150
  11. 11. Hyde KL, Samson F, Evans AC, Mottron L (2010) Neuroanatomical differences in brain areas implicated in perceptual and other core features of autism revealed by cortical thickness analysis and voxel-based morphometry. Hum Brain Mapp 31: 556–566. pmid:19790171
  12. 12. Fornito A, Yucel M, Wood SJ, Adamson C, Velakoulis D, et al. (2008) Surface-based morphometry of the anterior cingulate cortex in first episode schizophrenia. Hum Brain Mapp 29: 478–489. pmid:17525988
  13. 13. Fischl B (2012) FreeSurfer. Neuroimage 62: 774–781. pmid:22248573
  14. 14. Bogorodzki P, Piatkowska-Janko E, Szaflik J, Szaflik JP, Gacek M, et al. (2014) Mapping cortical thickness of the patients with unilateral end-stage open angle glaucoma on planar cerebral cortex maps. PLoS One 9: e93682. pmid:24709970
  15. 15. Yu L, Xie B, Yin X, Liang M, Evans AC, et al. (2013) Reduced cortical thickness in primary open-angle glaucoma and its relationship to the retinal nerve fiber layer thickness. PLoS One 8: e73208. pmid:24019910
  16. 16. Weinreb RN, Khaw PT (2004) Primary open-angle glaucoma. Lancet 363: 1711–1720. pmid:15158634
  17. 17. Krug K, Cicmil N, Parker AJ, Cumming BG (2013) A Causal Role for V5/MT Neurons Coding Motion-Disparity Conjunctions in Resolving Perceptual Ambiguity. Curr Biol 23: 1454–1459. pmid:23871244
  18. 18. Braddick OJ, O'Brien JM, Wattam-Bell J, Atkinson J, Hartley T, et al. (2001) Brain areas sensitive to coherent visual motion. Perception 30: 61–72. pmid:11257978
  19. 19. Cowey A, Campana G, Walsh V, Vaina LM (2006) The role of human extra-striate visual areas V5/MT and V2/V3 in the perception of the direction of global motion: a transcranial magnetic stimulation study. Exp Brain Res 171: 558–562. pmid:16708244
  20. 20. Chen Z, Lin F, Wang J, Li Z, Dai H, et al. (2013) Diffusion tensor magnetic resonance imaging reveals visual pathway damage that correlates with clinical severity in glaucoma. Clin Experiment Ophthalmol 41: 43–49. pmid:22712443
  21. 21. Mills RP, Budenz DL, Lee PP, Noecker RJ, Walt JG, et al. (2006) Categorizing the stage of glaucoma from pre-diagnosis to end-stage disease. Am J Ophthalmol 141: 24–30. pmid:16386972
  22. 22. Segonne F, Dale AM, Busa E, Glessner M, Salat D, et al. (2004) A hybrid approach to the skull stripping problem in MRI. Neuroimage 22: 1060–1075. pmid:15219578
  23. 23. Fischl B, Salat DH, van der Kouwe AJ, Makris N, Segonne F, et al. (2004) Sequence-independent segmentation of magnetic resonance images. Neuroimage 23 Suppl 1: S69–84. pmid:15501102
  24. 24. Segonne F, Pacheco J, Fischl B (2007) Geometrically accurate topology-correction of cortical surfaces using nonseparating loops. Ieee Transactions on Medical Imaging 26: 518–529. pmid:17427739
  25. 25. Fischl B, Dale AM (2000) Measuring the thickness of the human cerebral cortex from magnetic resonance images. Proc Natl Acad Sci U S A 97: 11050–11055. pmid:10984517
  26. 26. Hinds OP, Rajendran N, Polimeni JR, Augustinack JC, Wiggins G, et al. (2008) Accurate prediction of V1 location from cortical folds in a surface coordinate system. Neuroimage 39: 1585–1599. pmid:18055222
  27. 27. Fischl B, Rajendran N, Busa E, Augustinack J, Hinds O, et al. (2008) Cortical folding patterns and predicting cytoarchitecture. Cereb Cortex 18: 1973–1980. pmid:18079129
  28. 28. Malikovic A, Amunts K, Schleicher A, Mohlberg H, Eickhoff SB, et al. (2007) Cytoarchitectonic analysis of the human extrastriate cortex in the region of V5/MT+: a probabilistic, stereotaxic map of area hOc5. Cereb Cortex 17: 562–574. pmid:16603710
  29. 29. Rottschy C, Eickhoff SB, Schleicher A, Mohlberg H, Kujovic M, et al. (2007) Ventral visual cortex in humans: cytoarchitectonic mapping of two extrastriate areas. Hum Brain Mapp 28: 1045–1059. pmid:17266106
  30. 30. Wandell BA, Dumoulin SO, Brewer AA (2007) Visual field maps in human cortex. Neuron 56: 366–383. pmid:17964252
  31. 31. Fischl B, Sereno MI, Dale AM (1999) Cortical surface-based analysis. II: Inflation, flattening, and a surface-based coordinate system. Neuroimage 9: 195–207. pmid:9931269
  32. 32. Michelson G, Engelhorn T, Warntges S, El Rafei A, Hornegger J, et al. (2013) DTI parameters of axonal integrity and demyelination of the optic radiation correlate with glaucoma indices. Graefes Arch Clin Exp Ophthalmol 251: 243–253. pmid:22366916
  33. 33. Yucel Y, Gupta N (2008) Glaucoma of the brain: a disease model for the study of transsynaptic neural degeneration. Prog Brain Res 173: 465–478. pmid:18929128
  34. 34. Lam D, Jim J, To E, Rasmussen C, Kaufman PL, et al. (2009) Astrocyte and microglial activation in the lateral geniculate nucleus and visual cortex of glaucomatous and optic nerve transected primates. Mol Vis 15: 2217–2229. pmid:19898640
  35. 35. Fitzpatrick D, Lund JS, Blasdel GG (1985) Intrinsic connections of macaque striate cortex: afferent and efferent connections of lamina 4C. J Neurosci 5: 3329–3349. pmid:3001242
  36. 36. Lund JS (1988) Anatomical organization of macaque monkey striate visual cortex. Annu Rev Neurosci 11: 253–288. pmid:3284442
  37. 37. Luthra A, Gupta N, Kaufman PL, Weinreb RN, Yucel YH (2005) Oxidative injury by peroxynitrite in neural and vascular tissue of the lateral geniculate nucleus in experimental glaucoma. Exp Eye Res 80: 43–49. pmid:15652525
  38. 38. Ito M, Komatsu H (2004) Representation of angles embedded within contour stimuli in area V2 of macaque monkeys. J Neurosci 24: 3313–3324. pmid:15056711
  39. 39. Thomas OM, Cumming BG, Parker AJ (2002) A specialization for relative disparity in V2. Nat Neurosci 5: 472–478. pmid:11967544
  40. 40. El-Shamayleh Y, Kumbhani RD, Dhruv NT, Movshon JA (2013) Visual response properties of V1 neurons projecting to V2 in macaque. J Neurosci 33: 16594–16605. pmid:24133263
  41. 41. Lu HD, Chen G, Tanigawa H, Roe AW (2010) A motion direction map in macaque V2. Neuron 68: 1002–1013. pmid:21145011
  42. 42. Giaschi DE, Trope GE, Kothe AC, Hong XH (1996) Loss of sensitivity to motion-defined form in patients with primary open-angle glaucoma and ocular hypertension. J Opt Soc Am A Opt Image Sci Vis 13: 707–715. pmid:8867755
  43. 43. McKendrick AM, Badcock DR, Morgan WH (2005) The detection of both global motion and global form is disrupted in glaucoma. Invest Ophthalmol Vis Sci 46: 3693–3701. pmid:16186351
  44. 44. Roe AW, Ts'o DY (1995) Visual topography in primate V2: multiple representation across functional stripes. J Neurosci 15: 3689–3715. pmid:7751939
  45. 45. Merigan WH, Maunsell JH (1993) How parallel are the primate visual pathways? Annu Rev Neurosci 16: 369–402. pmid:8460898
  46. 46. Quigley HA, Dunkelberger GR, Green WR (1988) Chronic human glaucoma causing selectively greater loss of large optic nerve fibers. Ophthalmology 95: 357–363. pmid:3174003
  47. 47. Bradley DC, Chang GC, Andersen RA (1998) Encoding of three-dimensional structure-from-motion by primate area MT neurons. Nature 392: 714–717. pmid:9565031
  48. 48. Joffe KM, Raymond JE, Chrichton A (1997) Motion coherence perimetry in glaucoma and suspected glaucoma. Vision Res 37: 955–964. pmid:9156192
  49. 49. Karwatsky P, Bertone A, Overbury O, Faubert J (2006) Defining the nature of motion perception deficits in glaucoma using simple and complex motion stimuli. Optom Vis Sci 83: 466–472. pmid:16840871
  50. 50. Johansson BB (2004) Brain plasticity in health and disease. Keio J Med 53: 231–246. pmid:15647628
  51. 51. Chaturvedi N, Hedley-Whyte ET, Dreyer EB (1993) Lateral geniculate nucleus in glaucoma. Am J Ophthalmol 116: 182–188. pmid:8352303
  52. 52. Quigley HA, Dunkelberger GR, Green WR (1989) Retinal ganglion cell atrophy correlated with automated perimetry in human eyes with glaucoma. Am J Ophthalmol 107: 453–464. pmid:2712129
  53. 53. Li M, Liu F, Juusola M, Tang S (2014) Perceptual color map in macaque visual area V4. J Neurosci 34: 202–217. pmid:24381282
  54. 54. Ghose GM, Ts'o DY (1997) Form processing modules in primate area V4. J Neurophysiol 77: 2191–2196. pmid:9114265
  55. 55. Anzai A, Chowdhury SA, DeAngelis GC (2011) Coding of stereoscopic depth information in visual areas V3 and V3A. J Neurosci 31: 10270–10282. pmid:21753004
  56. 56. Wang MY, Wu K, Xu JM, Dai J, Qin W, et al. (2013) Quantitative 3-T diffusion tensor imaging in detecting optic nerve degeneration in patients with glaucoma: association with retinal nerve fiber layer thickness and clinical severity. Neuroradiology 55: 493–498. pmid:23358877