Ophthalmic application
Fundus Diseases:
Fundus photography, OCT/OCTA, FFA, and ICGA are used for the screening and diagnosis of fundus diseases.
Glaucoma:
Stereo optic disc and optic disc analysis assist doctors in diagnosing glaucoma and monitoring the progression of glaucoma.
Refractive Center:
Ultra-widefield fundus photography helps doctors screen for fundus lesions before surgery.
Cataract:
Anterior segment OCT serves to examine the cornea and lens prior to surgery, while posterior segment OCT is utilized in the detection of fundus pathologies.
Corneal Diseases:
Observation of corneal lesions and follow-up after treatment.
Pediatric Ophthalmology:
SKY's rapid, synchronized imaging enables shorter acquisition time, ideal for long-term follow-up after ROP treatment.
Physical Examination Application
The eyes are regarded as the "window" to systemic diseases. Many systemic diseases or systemic medications can cause ocular abnormalities or specific ocular changes. For example, systemic vascular diseases, metabolic diseases, infectious diseases, skin diseases, etc., may all lead to ocular damage. Ultra-widefield laser fundus cameras, with a wider observation range, clearer imaging, and more intelligent analysis and diagnosis technologies, provide services for various examination sites such as communities, institutions, and hospitals.
Diabetic Retinopathy
Age-Related Macular Degeneration
Endocrine Application
Chronic metabolic diseases such as diabetes are often accompanied by fundus lesions. Early detection of lesion signals is crucial for the management of such diseases and their complications. Ultra-widefield laser fundus cameras can conduct fundus examinations quickly and non-invasively, enabling timely detection of complications like diabetic retinopathy. With the assistance of artificial intelligence technology—known as the Retinal Assistant—doctors can save a significant amount of time spent on primary-level screening, improve screening efficiency, and facilitate early detection and early intervention.
Blood Vessels and Cones
Cones and blood flow were observed by confocal SLO under a non-adaptive optics (Non-AO) system, and quantitative research was carried out.
Cones
By obtaining parameters such as the average diameter and average density of cone cells, and through changes in the morphology, density, position and arrangement of cone cells, the relationship between changes in visual function in the avascular zone of the fovea and cone cells can be explored.
Blood Vessels
Observing the blood flow velocity, the condition of blood vessel walls, etc. can help clinicians understand the manifestations of microcirculation-related diseases and effectively achieve early analysis and prediction of retinal circulation disorders and systemic cardiovascular diseases.