Company
Introduction

Founded in 2011, Microclear Medical is positioned as a global high-end brand in ophthalmic imaging, focusing on the research and industrialization of eye health diagnostic equipment. Based on independent core hardware, the company integrates artificial intelligence and information technology to provide core technological products such as ultra-widefield SLO, ultra-wide and ultra-deep scanning OCT, and the SKY whole-eye imaging platform for ophthalmology, endocrinology, health check-ups, maternal and child health-care institutions.

The company has received various certifications both home and abroad, including China NMPA, US FDA, and EU CE.

In 2023, Microclear's ultra-widefield confocal fundus imaging system won the Ministry of Science and Technology's National Key R&D Program Special Award and the BCCIA Gold Award. In 2024, it was honored with the title of National Specialized and New "Little Giant" Enterprise and recognized as one of the Top Ten Original Advances in Ophthalmology in China. As of now, Microclear products have been installed in over 60 countries and regions, serving more than 1,500 hospitals and medical institutions worldwide.

Key Events
2011
The Company was Founded
2015
Obtained NMPA/CE/FDA certifications and released the first-generation fundus camera
2017
The first domestic confocal laser angiography machine was released, and it won the Suzhou Science and Technology Award as well as a series of certifications including ISO13485
2020
The first domestic ultra-wide-angle laser fundus camera was launched and included in the Catalog of Excellent Domestic Medical Devices
2023
Serving over 1,500 hospitals and medical institutions
2024
The installation quantity of confocal laser series products exceeds 500 units
2024
In November, the world's first SKY full-eye imaging platform was released
Technology and Clinical Research Publications

Shen, Y., Ye, X., Zhou, X., Yu, J., Zhang, C., He, S., Wu, J., Guan, H., Xu, G. and Shen, L., 2024.

In vivo assessment of cone loss and macular perfusion in children with myopia.

Scientific Reports, 14 (1), p.26373.

https://www.nature.com/articles/s41598-024-78280-y

Wu, S., Zheng, F., Sui, A., Wu, D. and Chen, Z., 2024.

Sodium-iodate injection can replicate retinal and choroid degeneration in pigmented mice: Using multimodal imaging and label-free quantitative proteomics analysis.

Experimental Eye Research, 247, p.110050.

https://www.sciencedirect.com/science/article/pii/S0014483524002719

Jiang, L., Wang, F., Zheng, R. and Li, C., 2023, November.

Cross-Domain Images Generation of Fundus Fluorescence Angiography Based on Generative Adversarial Networks with Self-Attention Mechanism.

In 2023 International Conference on Image Processing, Computer Vision and Machine Learning (ICICML) (pp. 6-10). IEEE.

Zhang, Y., Zheng, R., Hu, X., Li, C. and Wang, F., 2023, May.

An SVM-based method for classifying retinal lesion vessels.

In Second International Conference on Electronic Information Engineering, Big Data, and Computer Technology (EIBDCT 2023) (Vol. 12642, pp. 702-707). SPIE.

Liao, N., Li, C., Jiang, H., Fang. A., Zhou, S. and Wang, Q., 2016.

Neovascular glaucoma: a retrospective review from a tertiary center in China.

BMC ophthalmology, 16, pp.1-6.

Li, Chao hong, Hao Xian, Wenhan Jiang, Changhui Rao, 2012.

Measurement error of Shack-Hartmann wavefront sensor.

In Topics in Adaptive Optics. IntechOpen.

Hofer, H., Sredar, N., Queener, H., Li, C. and Porter, J., 2011.

Wavefront sensorless adaptive optics ophthalmoscopy in the human eye.

Optics express, 19(15), pp. 14160-14171.

Ivers, K.M., Li, C., Patel, N., Sredar, N., Luo, X., Queener, H., Harwerth, R.S. and Porter, J., 2011.

Reproducibility of measuring lamina cribrosa pore geometry in human and nonhuman primates with in vivo adaptive optics imaging.

Investigative ophthalmology & visual science, 52(8), pp.5473-5480.

Li, C., Sredar, N., Ivers, K.M., Queener, H. and Porter, J., 2010.

A correction algorithm to simultaneously control dual deformable mirrors in a woofer-tweeter adaptive optics system.

Optics express, 18(16), pp.16671-16684.

Li, Chaohong, et al, 2008.

Measuring statistical error of Shack-Hartmann wavefront sensor with discrete detector arrays.

Journal of Modern Optics, 55 (14), pp. 2243-2255.

Li, Chao hong., Xian, H., Jiang, W. and Rao, C., 2008.

Wavefront error caused by centroid position random error.

Journal of Modern Optics, 55 (1), pp. 127-133.

Li, Chao hong., Xian, H., Jiang, W. and Rao, C., 2007.

Performance analysis of field-of-view shifted Shack-Hartmann wavefront sensor based on splitter.

Applied Physics B, 88, pp.367-372.

Chao-Hong, L., Hao, X., Wen-Han, J. and Chang-Hui, R., 2007.

Analysis of wavefront measuring method for daytime adaptive optics.

Li, C., Xlan, H., Rao, C. and Jiang, W., 2006.

Field-of-view shifted Shack-Hartmann wavefront sensor for daytime adaptive optics system.

Optics letters, 31(19), pp. 2821-2823.