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Telemedicine: Remote monitoring of IOP through contact lenses . . . (23-3, July 2023) on:
106314 Wireless theranostic smart contact lens for monitoring and control of intraocular pressure in glaucoma
Kim TY; Mok JW; Hong SH et al.
Nature communications 2022; 13: 6801
Clinical Examination Methods: Intereye Symmetry of Circadian IOP Patterns (21-3, March 2021) on:
90231 Intereye Symmetry of 24-Hour Intraocular Pressure-related Patterns in Untreated Glaucoma Patients Using a Contact Lens Sensor
Mansouri K; Gillmann K
Journal of Glaucoma 2020; 29: 666-670
Pathogenesis: IOP and Posture (20-3, March 2020) on:
81419 Posture-Dependent 24-Hour Intraocular Pressure Fluctuation Patterns in an Intraocular Hypertension Monkey Model
Tu S; Li K; Hu D
Translational vision science & technology 2019; 8: 63
Progression: 24-hour IOP monitoring and Progression (20-2, November 2019) on:
77177 Association Between 24-Hour Intraocular Pressure Monitored With Contact Lens Sensor and Visual Field Progression in Older Adults With Glaucoma
De Moraes CG; Mansouri K; Liebmann JM et al.
JAMA ophthalmology 2018; 136: 779-785
Risk Factors in Glaucoma: Lurking in the Night: Blood Pressure Dips and Glaucoma (19-2, September 2018) on:
75672 Glaucomatous Optic Neuropathy Associated with Nocturnal Dip in Blood Pressure: Findings from the Maracaibo Aging Study
Melgarejo JD; Lee JH; Petitto M et al.
Ophthalmology 2018; 125: 807-814
Clinical Examination Methods: 24-h IOP Monitoring: Effect of Body Posture (18-4, December 2017) on:
72600 Twenty-four hour intraocular pressure monitoring with the SENSIMED Triggerfish contact lens: effect of body posture during sleep
Beltran-Agulló L; Buys YM; Jahan F et al.
British Journal of Ophthalmology 2017; 101: 1323-1328
Clinical Examination Methods: Reaching for the Brain: Can IOP help estimate Intracranial Pressure? (17-3, June 2016) on:
66262 System for Rapid, Precise Modulation of Intraocular Pressure, toward Minimally-Invasive In Vivo Measurement of Intracranial Pressure
Stockslager MA; Samuels BC; Allingham RR et al.
PLoS ONE 2016; 11: e0147020
Clinical Examination Methods: Telemetric tonomtery (16-4, September 2015) on:
60318 Implantation of a novel telemetric intraocular pressure sensor in patients with glaucoma (ARGOS study): 1-year results
Koutsonas A; Walter P; Roessler G et al.
Investigative Ophthalmology and Visual Science 2015; 56: 1063-1069
Risk Factors for Glaucoma: Preferred sleeping position (15-4, September 2014) on:
55523 Relationship between preferred sleeping position and asymmetric visual field loss in open-angle glaucoma patients
Kim KN; Jeoung JW; Park KH et al.
American Journal of Ophthalmology 2014; 157: 739-745
Miscellaneous: IOP and intracranial pressure in zero-gravity (14-3, April 2013) on:
51279 The translaminar pressure gradient in sustained zero gravity, idiopathic intracranial hypertension, and glaucoma
Berdahl JP; Yu DY; Morgan WH
Medical Hypotheses 2012; 79: 719-724
Intraocular Pressure: Circadian IOP patterns and visual field damage in NTG (14-1, November 2012) on:
48938 Circadian (24-hour) pattern of intraocular pressure and visual field damage in eyes with normal-tension glaucoma
Lee YR; Kook MS; Joe SG et al.
Investigative Ophthalmology and Visual Science 2012; 53: 881-887
Basic Research: CSF pressure in ocular hypertension (13-1, June 2011) on:
27725 Cerebrospinal fluid pressure in ocular hypertension
Ren R; Zhang X; Wang N et al.
Acta Ophthalmologica 2011; 89: 142-148
Intraocular Pressure and Outflow: IOP in sleeping with head-up (12-2, September 2010) on:
26306 Effect of sleeping in a head-up position on intraocular pressure in patients with glaucoma
Buys YM; Alasbali T; Jin YP et al.
Ophthalmology 2010; 117: 1348-1351
Intraocular Pressure: Wireless contact lens sensor (11-2, September 2009) on:
23776 Wireless contact lens sensor for intraocular pressure monitoring: assessment on enucleated pig eyes
Leonardi M; Pitchon EM; Bertsch A et al.
Acta Ophthalmologica 2009; 87: 433-437
IOP-Related: Melanopsis containing RGC and circadian rhythm (11-1, June 2009) on:
23051 Glaucoma alters the circadian timing system
Drouyer E; Dkhissi-Benyahya O; Chiquet C et al.
PLoS ONE 2008; 3: e3931
Basic research: Diurnal aqueous flow (10-2, September 2008) on:
21014 Circadian variation of aqueous dynamics in young healthy adults
Sit AJ; Nau CB; McLaren JW et al.
Investigative Ophthalmology and Visual Science 2008; 49: 1473-1479
Intraocular Pressure: IOP fluctuation and progression (9-3, December 2007) on:
19554 Diurnal intraocular pressure profiles and progression of chronic open-angle glaucoma
Jonas JB; Budde WM; Stroux A et al.
Eye 2007; 21: 948-951
Examination methods: IOP: 24-hrs Peak IOP registration (9-2, September 2007) on:
17581 Relationships between 24h observations in intraocular pressure vs blood pressure, heart rate, nitric oxide and age in the Medical Chronobiology Aging Project
Perlman JI; Delany CM; Sothern RB et al.
Clinica Terapeutica 2007; 158: 31-47
Intraocular pressure: 24-Hour fluctuation (9-1, June 2007) on:
17018 Circadian fluctuation of mean ocular perfusion pressure is a consistent risk factor for normal-tension glaucoma
Choi J; Kim KH; Jeong J et al.
Investigative Ophthalmology and Visual Science 2007; 48: 104-111
Clinical glaucoma: NPG - IOP (8-4, March 2007) on:
15103 Diurnal variation of intraocular pressure in suspected normal-tension glaucoma
Hasegawa K; Ishida K; Sawada A et al.
Japanese Journal of Ophthalmology 2006; 50: 449-454
Basic research: IOP: circadian rhythm (8-3, December 2006) on:
14031 Circadian intraocular pressure rhythm is generated by clock genes
Maeda A; Tsujiya S; Higashide T et al.
Investigative Ophthalmology and Visual Science 2006; 47: 4050-4052