Advancing Retinal Diagnostics With Multimodal Imaging

Lena Labs develops advanced imaging technologies to improve the detection and analysis of retinal disease.

400 - 1000

NM DETECTION RANGE

Visible to Near-IR

8

SPECTRAL CHANNELS

Simultaneous Capture

66 fps

REFLECTANCE MODE

Frame Rate

>97%

SPECTRAL ACCURACY

After AI Denoising

Multimodal Retinal Imaging

  • VISIBLE

    .

  • FAF

  • NIR

    .

CORE TECHNOLOGY

Engineered for spectral precision

The DuOS (Dual-mode Optical Spectroscopy) system integrates spectral reflectance and autofluorescence imaging within a single optical pathway, combining optics, electronics, and AI to capture what current retinal cameras cannot see.

Multimodal Hyperspectral Imaging

Combines broadband reflectance and autofluorescence within a single optical pathway. Three discrete excitation bands — 450 nm, 560 nm, 780 nm — enable blue, green, and near-infrared autofluorescence without mechanical realignment.

AI-Based Spectral Denoising

AI-based spectral denoising algorithms recover clinically usable signals under low-light imaging conditions while preserving spectral fidelity. This approach enhances signal quality without compromising spectral accuracy.

Broad Spectral Snapshot Detection

The system captures a wide spectral range spanning from visible to near-infrared wavelengths (400–1000 nm) within a single snapshot acquisition. This extended spectral capability supports enhanced biochemical and structural analysis of retinal biomarkers.

Integrated Calibration & Real-Time Spectral Processing

Integrated calibration and processing software enable real-time spectral analysis within a unified platform. The system supports consistent spectral performance and efficient data processing across imaging sessions.

LENA LABS

Lena Labs focuses on the development of multimodal spectral imaging systems for retinal diagnostics and clinical research.

Its flagship platform, the Lena DuOS (Dual-mode Optical Spectroscopy) System, integrates spectral reflectance and autofluorescence imaging within a compact architecture to support comprehensive retinal tissue characterization.

Clinical Applications

Revealing what conventional imaging cannot

Age-Related Macular Degeneration

Spectral reflectance and autofluorescence signatures enable quantification of drusen, lipofuscin, and RPE integrity — biomarkers that remain invisible to standard color fundus photography.

Geographic Atrophy

Spectral reflectance and autofluorescence signatures enable quantification of drusen, lipofuscin, and RPE integrity — biomarkers that remain invisible to standard color fundus photography.