Convolutional neural network-based classification of glaucoma using optic radiation tissue properties

Kruper, J.; Richie-Halford, A.; Benson, N. C.; Caffarra, S.; Owen, J.; Wu, Y.; Egan, C.; Lee, A. Y.; Lee, C. S.; Yeatman, J. D.; Rokem, A.; Zheng, Y.; Yates, M.; Woodside, J.; Williams, C.; Williams, K.; Weedon, M.; Vitart, V.; Viswanathan, A.; Tufail, A.; Trucco, E.; Thomas, M.; Thomas, D.; Tapp, R.; Sun, Z.; Sudlow, C.; Strouthidis, N.; Stratton, I.; Steel, D.; Sivaprasad, S.; Sergouniotis, P.; Self, J.; Sattar, N.; Rudnicka, A.; Rahi, J.; Pontikos, N.; Petzold, A.; Peto, T.; Paterson, E.; Patel, P.; Owen, C.; Oram, R.; O'Sullivan, E.; Morgan, J.; Moore, T.; Mckibbin, M.; Mckay, G.; Mcguinness, B.; Madhusudhan, S.; Mackie, S.; Macgillivray, T.; Luthert, P.; Luben, R.; Lotery, A.; Littlejohns, T.; Lascaratos, G.; Khawaja, A.; Khaw, P. T.; Keane, P.; Hysi, P.; Hogg, R.; Harding, S.; Hardcastle, A.; Hammond, C.; Guggenheim, J.; Gibson, J.; Garway-Heath, D.; Gallacher, J.; Fruttiger, M.; Foster, P.; Ennis, S.; Egan, C.; Doney, A.; Dick, A.; Dhillon, B.; Desai, P.; Day, A.; Chua, S.; Chan, M.; Chakravarthy, U.; Carare, R.; Braithwaite, T.; Black, G.; Bishop, P.; Barrett, J.; Barman, S.; Balaskas, K.; Atan, D.; Aslam, T.; Allen, N.

doi:10.1038/s43856-024-00496-w

Background: Sensory changes due to aging or disease can impact brain tissue. This study aims to investigate the link between glaucoma, a leading cause of blindness, and alterations in brain connections. Methods: We analyzed diffusion MRI measurements of white matter tissue in a large group, consisting of 905 glaucoma patients (aged 49-80) and 5292 healthy individuals (aged 45-80) from the UK Biobank. Confounds due to group differences were mitigated by matching a sub-sample of controls to glaucoma subjects. We compared classification of glaucoma using convolutional neural networks (CNNs) focusing on the optic radiations, which are the primary visual connection to the cortex, against those analyzing non-visual brain connections. As a control, we evaluated the performance of regularized linear regression models. Results: We showed that CNNs using information from the optic radiations exhibited higher accuracy in classifying subjects with glaucoma when contrasted with CNNs relying on information from non-visual brain connections. Regularized linear regression models were also tested, and showed significantly weaker classification performance. Additionally, the CNN was unable to generalize to the classification of age-group or of age-related macular degeneration. Conclusions: Our findings indicate a distinct and potentially non-linear signature of glaucoma in the tissue properties of optic radiations. This study enhances our understanding of how glaucoma affects brain tissue and opens avenues for further research into how diseases that affect sensory input may also affect brain aging.

Convolutional neural network-based classification of glaucoma using optic radiation tissue properties / Kruper, J.; Richie-Halford, A.; Benson, N. C.; Caffarra, S.; Owen, J.; Wu, Y.; Egan, C.; Lee, A. Y.; Lee, C. S.; Yeatman, J. D.; Rokem, A.; Zheng, Y.; Yates, M.; Woodside, J.; Williams, C.; Williams, K.; Weedon, M.; Vitart, V.; Viswanathan, A.; Tufail, A.; Trucco, E.; Thomas, M.; Thomas, D.; Tapp, R.; Sun, Z.; Sudlow, C.; Strouthidis, N.; Stratton, I.; Steel, D.; Sivaprasad, S.; Sergouniotis, P.; Self, J.; Sattar, N.; Rudnicka, A.; Rahi, J.; Pontikos, N.; Petzold, A.; Peto, T.; Paterson, E.; Patel, P.; Owen, C.; Oram, R.; O'Sullivan, E.; Morgan, J.; Moore, T.; Mckibbin, M.; Mckay, G.; Mcguinness, B.; Madhusudhan, S.; Mackie, S.; Macgillivray, T.; Luthert, P.; Luben, R.; Lotery, A.; Littlejohns, T.; Lascaratos, G.; Khawaja, A.; Khaw, P. T.; Keane, P.; Hysi, P.; Hogg, R.; Harding, S.; Hardcastle, A.; Hammond, C.; Guggenheim, J.; Gibson, J.; Garway-Heath, D.; Gallacher, J.; Fruttiger, M.; Foster, P.; Ennis, S.; Egan, C.; Doney, A.; Dick, A.; Dhillon, B.; Desai, P.; Day, A.; Chua, S.; Chan, M.; Chakravarthy, U.; Carare, R.; Braithwaite, T.; Black, G.; Bishop, P.; Barrett, J.; Barman, S.; Balaskas, K.; Atan, D.; Aslam, T.; Allen, N.. - In: COMMUNICATIONS MEDICINE. - ISSN 2730-664X. - 4:1(2024), pp. N/A-N/A. [10.1038/s43856-024-00496-w]

Convolutional neural network-based classification of glaucoma using optic radiation tissue properties

Kruper J.;Richie-Halford A.;Benson N. C.;Caffarra S.;Owen J.;Wu Y.;Egan C.;Lee A. Y.;Lee C. S.;Yeatman J. D.;Rokem A.;Zheng Y.;Yates M.;Woodside J.;Williams C.;Williams K.;Weedon M.;Vitart V.;Viswanathan A.;Tufail A.;Trucco E.;Thomas M.;Thomas D.;Tapp R.;Sun Z.;Sudlow C.;Strouthidis N.;Stratton I.;Steel D.;Sivaprasad S.;Sergouniotis P.;Self J.;Sattar N.;Rudnicka A.;Rahi J.;Pontikos N.;Petzold A.;Peto T.;Paterson E.;Patel P.;Owen C.;Oram R.;O'Sullivan E.;Morgan J.;Moore T.;McKibbin M.;McKay G.;McGuinness B.;Madhusudhan S.;Mackie S.;MacGillivray T.;Luthert P.;Luben R.;Lotery A.;Littlejohns T.;Lascaratos G.;Khawaja A.;Khaw P. T.;Keane P.;Hysi P.;Hogg R.;Harding S.;Hardcastle A.;Hammond C.;Guggenheim J.;Gibson J.;Garway-Heath D.;Gallacher J.;Fruttiger M.;Foster P.;Ennis S.;Egan C.;Doney A.;Dick A.;Dhillon B.;Desai P.;Day A.;Chua S.;Chan M.;Chakravarthy U.;Carare R.;Braithwaite T.;Black G.;Bishop P.;Barrett J.;Barman S.;Balaskas K.;Atan D.;Aslam T.;Allen N.

2024

Abstract

Background: Sensory changes due to aging or disease can impact brain tissue. This study aims to investigate the link between glaucoma, a leading cause of blindness, and alterations in brain connections. Methods: We analyzed diffusion MRI measurements of white matter tissue in a large group, consisting of 905 glaucoma patients (aged 49-80) and 5292 healthy individuals (aged 45-80) from the UK Biobank. Confounds due to group differences were mitigated by matching a sub-sample of controls to glaucoma subjects. We compared classification of glaucoma using convolutional neural networks (CNNs) focusing on the optic radiations, which are the primary visual connection to the cortex, against those analyzing non-visual brain connections. As a control, we evaluated the performance of regularized linear regression models. Results: We showed that CNNs using information from the optic radiations exhibited higher accuracy in classifying subjects with glaucoma when contrasted with CNNs relying on information from non-visual brain connections. Regularized linear regression models were also tested, and showed significantly weaker classification performance. Additionally, the CNN was unable to generalize to the classification of age-group or of age-related macular degeneration. Conclusions: Our findings indicate a distinct and potentially non-linear signature of glaucoma in the tissue properties of optic radiations. This study enhances our understanding of how glaucoma affects brain tissue and opens avenues for further research into how diseases that affect sensory input may also affect brain aging.

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	Anno di pubblicazione
	
				2024
			
	Rivista
	
				COMMUNICATIONS MEDICINE
			
	N° del Volume
	
				4
			
	Fascicolo
	
				1
			
	Pagina iniziale
	
				N/A
			
	Pagina finale
	
				N/A
			
	Codice DOI
	
				https://dx.doi.org/10.1038/s43856-024-00496-w
			
	Codice WoS
	
				WOS:001200420100002
			
	Codice Scopus
	
				2-s2.0-85198529109
			
	Codice PubMed
	
				38605245
			
	Citazione
	
				Convolutional neural network-based classification of glaucoma using optic radiation tissue properties / Kruper, J.; Richie-Halford, A.; Benson, N. C.; Caffarra, S.; Owen, J.; Wu, Y.; Egan, C.; Lee, A. Y.; Lee, C. S.; Yeatman, J. D.; Rokem, A.; Zheng, Y.; Yates, M.; Woodside, J.; Williams, C.; Williams, K.; Weedon, M.; Vitart, V.; Viswanathan, A.; Tufail, A.; Trucco, E.; Thomas, M.; Thomas, D.; Tapp, R.; Sun, Z.; Sudlow, C.; Strouthidis, N.; Stratton, I.; Steel, D.; Sivaprasad, S.; Sergouniotis, P.; Self, J.; Sattar, N.; Rudnicka, A.; Rahi, J.; Pontikos, N.; Petzold, A.; Peto, T.; Paterson, E.; Patel, P.; Owen, C.; Oram, R.; O'Sullivan, E.; Morgan, J.; Moore, T.; Mckibbin, M.; Mckay, G.; Mcguinness, B.; Madhusudhan, S.; Mackie, S.; Macgillivray, T.; Luthert, P.; Luben, R.; Lotery, A.; Littlejohns, T.; Lascaratos, G.; Khawaja, A.; Khaw, P. T.; Keane, P.; Hysi, P.; Hogg, R.; Harding, S.; Hardcastle, A.; Hammond, C.; Guggenheim, J.; Gibson, J.; Garway-Heath, D.; Gallacher, J.; Fruttiger, M.; Foster, P.; Ennis, S.; Egan, C.; Doney, A.; Dick, A.; Dhillon, B.; Desai, P.; Day, A.; Chua, S.; Chan, M.; Chakravarthy, U.; Carare, R.; Braithwaite, T.; Black, G.; Bishop, P.; Barrett, J.; Barman, S.; Balaskas, K.; Atan, D.; Aslam, T.; Allen, N.. - In: COMMUNICATIONS MEDICINE. - ISSN 2730-664X. - 4:1(2024), pp. N/A-N/A. [10.1038/s43856-024-00496-w]
			
	Tutti gli autori
	
						Kruper, J.; Richie-Halford, A.; Benson, N. C.; Caffarra, S.; Owen, J.; Wu, Y.; Egan, C.; Lee, A. Y.; Lee, C. S.; Yeatman, J. D.; Rokem, A.; Zheng, Y.;...espandi
						
	Tipologia
	
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