Retinal vasculature enhancement using independent component analysis

Ahmad Fadzil M. Hani; Hanung Adi Nugroho

doi:10.4236/jbise.2009.27079

Journal of Biomedical Science and Engineering > Vol.2 No.7, November 2009

Retinal vasculature enhancement using independent component analysis

Ahmad Fadzil M. Hani, Hanung Adi Nugroho
.
DOI: 10.4236/jbise.2009.27079 PDF HTML 6,090 Downloads 11,609 Views Citations

Abstract

Retinal vasculature is a network of vessels in the retinal layer. In ophthalmology, information of retinal vasculature in analyzing fundus images is important for early detection of diseases related to the retina, e.g. diabetic retinopathy. However, in fundus images the contrast between retinal vasculature and the background is very low. As a result, analyzing or visualizing tiny retinal vasculature is difficult. There-fore, enhancement of retinal vasculature in digital fundus image is important to provide better visualization of retinal blood vessels as well as to increase accuracy of retinal vasculature segmentation. Fluorescein angiogram overcomes this imaging problem but it is an invasive procedure that leads to other physiological problems. In this research work, the low contrast problem of retinal fundus images ob-tained from fundus camera is addressed. We develop a fundus image model based on probability distribution function of melanin, haemoglobin and macular pigment to represent melanin, retinal vasculature and macular region, respectively. We determine retinal pigments makeup, namely macular pigment, melanin and haemoglobin using independent component analysis. Independent component image due to haemoglobin obtained is used since it exhibits higher contrast retinal vasculature. Contrast of reti-nal vasculature from independent component image due to haemoglobin is compared to those from other enhancement methods. Results show that this approach outperforms other non-invasive enhancement methods, such as contrast stretching, histogram equalization and CLAHE and can be beneficial for retinal vasculature segmentation. Contrast enhancement factor up to 2.62 for a digital retinal fundus image model is achieved. This improvement in contrast reduces the need of applying contrasting agent on patients.

Keywords

Contrast Enhancement; Independent Comp- onent Analysis; Medical Image Processing; Retinal Fundus Image

Share and Cite:

Fadzil M. Hani, A. and Adi Nugroho, H. (2009) Retinal vasculature enhancement using independent component analysis. Journal of Biomedical Science and Engineering, 2, 543-549. doi: 10.4236/jbise.2009.27079.

Conflicts of Interest

The authors declare no conflicts of interest.

References

[1]	Staal, J., Abramoff, M. D., Niemeijer, M., Viergever, M. A., and Ginneken van B., (2004) Ridge-based vessel segmentation in color images of the retina, Medical Imaging, IEEE Transac-tions, 23, 501–509.
[2]	Niemeijer, M., Staal, J., Ginneken v. B., Loog M., and Abramoff M. D., (2004) Comparative study of retinal vessel segmentation methods on a new publicly available database, Medical Imaging: Image Processing, Milan, 648–656.
[3]	Shimahara, T., Okatani, T., and Deguchi, K., (2004) Contrast enhancement of fundus images using regional histograms for medical diagnosis, SICE Annual Conference, 1, 650–653.
[4]	Sinthanayothin, C., Kongbunkiat, V., Phoojaruenchana- chai, S., and Singalavanija, A., (2003) Automated screen- ing system for diabetic retinopathy, Image and Signal Processing and Analysis, ISPA, Proceedings of the 3rd International Sympo-sium on, 915.
[5]	Wu, D., Zhang, M., Liu, J. C., and Bauman, W., (2006) On the adaptive detection of blood vessels in retinal images, Bio-medical Engineering, IEEE Transactions on, 53, 341–343.
[6]	Yang, S., Oh, J. H., and Park, Y., (2003) Contrast enhancement using histogram equalization with bin underflow and bin over-flow, in Image Processing, ICIP, Proceedings International Conference on, 1, I–881–4.
[7]	Fadzil, M. H. A., Izhar, L. I., Venkatachalam, P. A., and Ka-runakar, T. V. N., (2007) Extraction and reconstruction of reti-nal vasculature, Journal of Medical Engineering Technology, 31, 435–442.
[8]	Iznita, L., (2006) Analysis of retinal vasculature and foveal avascular zone for grading of diabetic retinopathy, in M.Sc, Thesis Electrical and Electronics Engineering Programme Bandar Seri Iskandar, Malaysia, Universiti Teknologi PETRONAS.
[9]	Tsumura, N., Haneishi, H., and Miyake, Y., (1999) Independ-ent-component analysis of skin color image, J. Opt. Soc. Am. A, 16, 2169.
[10]	Nugroho, H., Fadzil, M. H. A., Yap, V. V., Norashikin, S., and Suraiya, H. H., (2007) Determination of Skin Repi- gmentation Progression, Engineering in Medicine and Biology Society, EMBS Annual International Conference of the IEEE, 3442.
[11]	Preece, S. J. and Claridge, E., (2002) Physics Based Medical Image Understanding of the Colouration of the Ocular Fundus with Application to Detection of Diabetic Retinopathy, De-partment of Computer Science, University of Birmingham, Edgbaston, Birmingham Technical Report CSR–04–08.
[12]	Orihuela-Espina, F., Claridge, E., and Preece, S. J., (2003) Histological parametric maps of the human ocular fundus: preliminary results, Medical Image Understanding and Analy-sis, 133–136.
[13]	Styles, I. B., Calcagni, A., Claridge, E., Orihuela-Espina, F., and Gibson, J. M., (2006) Quantitative analysis of multi-spectral fundus images, Medical Image Analysis: Special Issue on Functional Imaging and Modelling of the Heart (FIMH 2005), 10, 578–597.
[14]	Tsumura, N., Haneishi, H., and Miyake, Y., (2000) Independent Component Analysis of Spectral Absorbance Image in Human Skin, Optical Review, 7, 479–482.
[15]	Knighton, R. W., (1995) Quantitative reflectometry of the ocu-lar fundus, Engineering in Medicine and Biology Magazine, IEEE, 14, 43–51.
[16]	Berendschot, T. T. J. M., DeLint, P. J., and Norren, D., (2003) Fundus reflectance-historical and present ideas, Progress in Retinal and Eye Research, 22, 171–200.
[17]	Ahmad Fadzil, M. H., Nugroho, H. A., Venkatachalam, P. A., Nugroho, H., and Izhar, L. I., (2008) Determination of Retinal Pigments from Fundus Images using Independent Component Analysis, in Biomed 4th Kuala Lumpur International Confer-ence on Biomedical Engineering, Kuala Lumpur, 555–558.
[18]	Comon, P., (1994) Independent component analysis, A new concept?, Signal Processing, 36, 287.
[19]	Hyvarinen, A. and Oja, E., (2000) Independent compo- nent analysis: algorithms and applications, Neural Networks, 13, 411.
[20]	Hyvarinen, E., (1999) Fast and robust fixed-point algorithms for independent component analysis, Neural Networks, IEEE Transactions on, 10, 626–634.
[21]	Cardoso, J. F. and Souloumiac, A., (1999) Blind beamforming for non Gaussian signals, IEE Proceedings-F, 140, 362–370.
[22]	Bell, A. J. and Sejnowski, T. J., (1995) An informa-tion-maximisation approach to blind separation and blind de-convolution, Neural Computation, 7, 1129–1159.
[23]	Ahmad Fadzil, M. H., Nugroho, H. A., Nugroho, H., and Izhar, L. I., (2009) Fundus Image Database for Non Invasive Diabetic Retinopathy Monitoring and Grading System (FINDeRS), Universiti Teknologi PETRONAS.
[24]	Adelmann, H. G., (1998) Butterworth equations for ho- mo-morphic filtering of images, Computers in Biology and Medi-cine, 28, 169–181.

Journals Menu

Follow SCIRP

	+1 323-425-8868
	customer@scirp.org
	+86 18163351462(WhatsApp)
	1655362766

	Paper Publishing WeChat

Journals Menu

Home

About SCIRP

Service

Policies