Clinical Study - ES 900 - 2020-1

Not Applicable

• Conditions: Cataract
• Interventions: Device: EYESTAR 900; Device: LENSTAR LS 900

• Registration Number: NCT05304182
• Lead Sponsor: Haag-Streit AG

Brief Summary

EYESTAR 900 is a device developed by Haag-Streit which utilises 3D OCT for quantitative measurements of the geometry of the entire eye, including ocular biometry and corneal topography. It is the most recent in a series of successful biometry devices by Haag-Streit (HS Pachymeter, Lenstar LS 900, LS 900 T-cone and LS 900 APS) and also allows for advanced corneal tomography examinations. The EYESTAR 900 is CE marked.

These measurement results of this device are used for the planning of the medical treatment of patients. Depending on the application, the benefits of this device may include improved visual acuity (after cataract surgery), reduced risk of complications (after refractive surgery or implant of a phakic intraocular lens), early identification of pathological deformations of the cornea (keratoconus detection).

The primary objective of this clinical trial is to assess the clinical performance of the investigational device in dense cataracts. To that end, for each measurand, the in-vivo repeatability will be quantified, as well as limits of agreement and the mean measurement deviation, with respect to the current gold standard device.

As a secondary objective of the study, raw measurement data will be collected to allow for the improvement of existing algorithms, development of additional measurands and for retrospective analysis.

No diseases are studied.

Detailed Description

The EYESTAR 900 is a non-contact device for measuring the human eye, consisting of a swept source OCT sub-unit (OCT: optical coherence tomography, a measurement method to acquire tomographic images by optical interferometry) and an imaging system sub-unit.

The OCT sub-unit performs a three-dimensional measurement of all refractive ocular structures in the anterior eye segment (curvatures and locations of the anterior corneal surface, posterior corneal surface, the anterior crystalline lens surface, posterior crystalline lens surface), as well as a one-dimensional measurement of axial eye length. It also generates cross-sectional images of the anterior eye section and the central retina. The measurement is implemented by scanning the eye with a low-power near-infrared laser beam and measuring the light which is back-reflected to the device.

The imaging system sub-unit is used to obtain photographic images of the eye. Based on these images, the keratometry (anterior corneal curvature of the steepest and flattest meridian), the white-to-white distance and the pupil diameter are measured. Additionally, these images can serve to document the locations of special landmarks on the eye, such as blood vessels. The imaging system sub-unit is based on conventional digital photography technology. Illumination for imaging is provided by infrared and white-light LEDs (light emitting diodes). Measurement of keratometry additionally requires measuring the distance to the eye using the OCT sub-unit.

The EYESTAR 900 is designed as standalone-device with integrated PC (personal computer) and display for device operation, measurement acquisition and processing, and presentation of the measurement results. After a patient is placed in front of the device and the chin rest is adjusted, the device can perform the remaining positioning procedures and acquire the measurements in a fully automated manner. Position information is derived from the OCT and digital camera system sub-units.

Both implemented measuring methods, optical coherence tomography (OCT), as well as digital photography are non-invasive, contactless methods. OCT uses a laser beam of λ=1060nm central wavelength and less than 2 mW optical power, which is focussed to a beam diameter of approximately 80µm at the anterior lens plane, and is continuously scanned in the lateral direction. Digital photography uses diffuse illumination of the eye by white-light LEDs (425nm ≤ λ ≤ 725nm) and infrared LEDs with central wavelength λ=850nm. All light sources emit levels that comply with ISO 15004-2 ("Ophthalmic Instruments - Fundamental requirements and test methods - Part 2: Light hazard protection"), under normal operating conditions as well as in case of a single fault condition.

The main application of this device is to acquire biometric measurements of cataractous eyes which are used to calculate suitable intraocular lens power and dimension.

The patient population must be capable of sitting up straight and keeping their head still and their eyes opened. They must be physically and mentally able to cooperate and mentally capable of following the examination. Patients must be at least 18 years old.

The target device user is an ophthalmologist or a trained specialist.

The investigational device EYESTAR 900 is developed and manufactured by HAAG-STREIT AG, Koeniz (Switzerland).

For the duration of the examination (approximately 1-2 minutes), the patient is in contact with the device at following applied parts:

1. the chin rest shell (Edistir RK451 G naturally coated with HAERATEX Aqua 2K-structural coater BW89 10K RAL 9005);

2. the forehead rest band (Saxamid 126-N001 uncoated PA6 white FK 6659 PA);

3. (depending on the subject's requirements) the patient handles (aluminium EN AW-6060 (AlMgSi 0.5) colourless anodized class 20 with sealing chemically polished and sandblasted).

No other contact with body tissues or fluids takes place. No critical biocompatibility issues were identified.

Study Timeline

• Study First Submitted: 2022-03-22
• Study First Submitted QC: 2022-03-22
• Study First Posted: 2022-03-31
• Status Verified: 2022-06
• Last Update Submitted: 2022-06-22
• Last Update Posted: 2022-06-29
• Study Start: 2022-07-01
• Primary Completion: 2023-12-30
• Study Completion: 2024-02-28

Recruitment & Eligibility

• Status: UNKNOWN
• Sex: All
• Target Recruitment: 50

Inclusion Criteria

• voluntary participation
• informed consent
• 35 years of age or older

Exclusion Criteria

• ineligibility for cataract surgery for any reason, e.g., aphakia

• Disqualifying pathologies:

  • keratoconus
  • corneal astigmatism of more than 3.5 D
  • history of recurrent inflammation or infection of the eye

• Disqualifying corneal conditions:

  • comorbidities,
  • deformations,
  • lesions, or
  • scarring of the cornea
  • acute inflammation or infection of the eye

• Disqualifying treatments:

  • previous refractive surgeries, including PRK and LASIK
  • previous corneal surgeries
  • previous corneal transplants
  • previous intraocular surgeries

• Disqualifying outcomes:

  • failed IOL implantation into the capsular bag

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: CROSSOVER

Arm && Interventions

Group	Intervention	Description
Pre-Op	EYESTAR 900	The experimental intervention is non-invasive optical imaging, in particular digital photography and optical coherence tomography, conducted with the investigational and comparator device, for the purpose of measuring dimensions of the eye.
Post-Op	EYESTAR 900	The experimental intervention is non-invasive optical imaging, in particular digital photography and optical coherence tomography, conducted with the investigational and comparator device, for the purpose of measuring dimensions of the eye.
Pre-Op	LENSTAR LS 900	The experimental intervention is non-invasive optical imaging, in particular digital photography and optical coherence tomography, conducted with the investigational and comparator device, for the purpose of measuring dimensions of the eye.
Post-Op	LENSTAR LS 900	The experimental intervention is non-invasive optical imaging, in particular digital photography and optical coherence tomography, conducted with the investigational and comparator device, for the purpose of measuring dimensions of the eye.

Primary Outcome Measures

Name	Time	Method
Dense Cataract Performance	18 months	The primary outcome is the performance of the EYESTAR 900 in dense cataracts. Specifically, the highest grade of cataract at which complete measurements can reliably be performed and, consequently, the number of patients measured successfully.

Secondary Outcome Measures

Name	Time	Method
Keratometry	18 months	The limits of agreement and the confidence interval of difference in comparison with the LENSTAR 900.
Anterior Corneal Axial Curvature	18 months	The limits of agreement and the confidence interval of difference in comparison with the LENSTAR 900.
Posterior Corneal Elevation	18 months	The limits of agreement and the confidence interval of difference in comparison with the LENSTAR 900.
Posterior Corneal Axial Curvature	18 months	The limits of agreement and the confidence interval of difference in comparison with the LENSTAR 900.
Simulated Posterior Keratometry	18 months	The limits of agreement and the confidence interval of difference in comparison with the LENSTAR 900.
Axial Length	18 months	The limits of agreement and the confidence interval of difference in comparison with the LENSTAR 900.
Anterior Corneal Elevation	18 months	The limits of agreement and the confidence interval of difference in comparison with the LENSTAR 900.
Anterior Corneal Tangential Curvature	18 months	The limits of agreement and the confidence interval of difference in comparison with the LENSTAR 900.
Posterior Corneal Tangential Curvature	18 months	The limits of agreement and the confidence interval of difference in comparison with the LENSTAR 900.
Corneal Pachymetry	18 months	The limits of agreement and the confidence interval of difference in comparison with the LENSTAR 900.
Simulated Anterior Keratometry	18 months	The limits of agreement and the confidence interval of difference in comparison with the LENSTAR 900.
White-to-White Imaging	18 months	The limits of agreement and the confidence interval of difference in comparison with the LENSTAR 900.

Trial Locations

Locations (1)

Aravind Eye Hospitals; 🇮🇳 Chennai, Tamil Nadu, India