Use of a novel telemetric sensor to study interactions of intraocular pressure and ganglion-cell function in glaucoma.
Al-Nosairy Khaldoon O, van den Bosch Jacqueline J O N, Pennisi Vincenzo, Mansouri Kaweh, Thieme Hagen, Choritz Lars, Hoffmann Michael B
AI Summary
This study explored simultaneous IOP and ganglion cell function (PERG) using an implanted sensor. It found lateral positioning affects both IOP and PERG, suggesting this model can help understand how IOP impacts ganglion cells in glaucoma.
Abstract
Aims
(1) To test the feasibility of simultaneous steady-state pattern electroretinogram (ssPERG) and intraocular pressure (IOP) measurements with an implanted IOP sensor. (2) To explore the scope of this approach for detecting PERG changes during IOP manipulation in a model of lateral decubitus positioning (LDP; lateral position).
Methods
15 healthy controls and 15 treated glaucoma patients participated in the study. 8 patients had an IOP sensor (Eyemate-IO, Implandata Ophthalmic Products GmbH) in the right eye (GLA IMP ) and 7 had no sensor and with glaucoma in the left eye. (1) We compared PERGs with and without simultaneous IOP read-out in GLA IMP . (2) All participants were positioned in the following order: sitting1 (S1), right LDP (LD R ), sitting2 (S2), left LDP (LD L ) and sitting3 (S3). For each position, PERG amplitudes and IOP were determined with rebound tonometry (Icare TA01i) in all participants without the IOP sensor.
Results
Electromagnetic intrusions of IOP sensor read-out onto ssPERG recordings had, due to different frequency ranges, no relevant effect on PERG amplitudes. IOP and PERG measures were affected by LDP, for example, IOP was increased during LD R versus S1 in the lower eyes of GLA IMP and controls (5.1±0.6 mmHg, P 0.025 =0.00004 and 1.6±0.6 mmHg, P 0.025 =0.02, respectively) and PERG amplitude was reversibly decreased (-25±10%, P 0.025 =0.02 and -17±5%, P 0.025 , respectively).
Conclusions
During LDP, both IOP and PERG changed predominantly in the lower eye. IOP changes induced by LDP may be a model for studying the interaction of IOP and ganglion-cell function.
MeSH Terms
Shields Classification
Key Concepts5
Intraocular pressure (IOP) was increased during right lateral decubitus positioning (LD R) versus sitting1 (S1) in the lower eyes of glaucoma patients with an implanted IOP sensor (GLA IMP) by 5.1±0.6 mmHg (P = 0.00004) and in healthy controls by 1.6±0.6 mmHg (P = 0.02).
Steady-state pattern electroretinogram (PERG) amplitude was reversibly decreased by -25±10% (P = 0.02) in glaucoma patients with an implanted IOP sensor (GLA IMP) and by -17±5% (P = 0.025) in healthy controls during lateral decubitus positioning (LDP).
During lateral decubitus positioning (LDP), both intraocular pressure (IOP) and steady-state pattern electroretinogram (PERG) changes predominantly occurred in the lower eye of both healthy controls and treated glaucoma patients.
Electromagnetic intrusions from the implanted IOP sensor (Eyemate-IO, Implandata Ophthalmic Products GmbH) did not significantly affect steady-state pattern electroretinogram (ssPERG) recordings due to different frequency ranges in glaucoma patients.
Intraocular pressure (IOP) changes induced by lateral decubitus positioning (LDP) may serve as a model for studying the interaction of IOP and ganglion-cell function in glaucoma.
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