Wet Field Bi-Polar Surgical Treatment for Retinopathy

V.Manikandan; Kovuru Reddy Sai; Kancharla Ganga Ravindra Reddy; Shaik Mohammed Musaib; Chamala Balanna Gari Indrasena Reddy1

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Publication Date: 2024/05/09

Abstract: Retinopathy is a major cause due to high blood sugar and it affects the major nerves damage in the back of our eyes. This poor management of sugar levels in our daily intakes and it initiates major cause in human vision. Diabetic retinopathy rectification has most important favored for the every patient whose are affected by the diabetic mellitus. Surgery and surgical instrument based retinopathy has a most featured approach. Wet-field bi- polar cautery is an instrument to reduce the unwanted progressive tissue in our eyes. This device or temperature generated has controlled with the aid of sensor and microcontroller devices. This sensor based temperature optimization has increased the performance of the device. The current scenarios of the device and temperature level have explicated via various electronic devices and improve the surgical performance. Thus the efficiency and effectiveness of the system has most useful for the diabetic retinopathy patients.

Keywords: Bi-Polar Devices, Retinopathy Surgical Treatment, Diabetic Mellitus.

DOI: https://doi.org/10.38124/ijisrt/IJISRT24APR2274

PDF: https://ijirst.demo4.arinfotech.co/assets/upload/files/IJISRT24APR2274.pdf

REFERENCES

  1. Matsuo, T., Uchida, T., Yamashita, K., Tanaka, T., Kawakami, Y., Hitomi, T., Taga, K., Sanada, T. and Yamashita, Y., 2020. Curved-tip disposable injector (OUReP Injector) to insert photoelectric dye-coupled polyethylene film (OUReP) as retinal prosthesis into subretinal space of rabbit eyes. Journal of Surgical Techniques and Procedures4(3), p.1040.
  2. Mahar, P.S., Tabassum, S., Inam, M., Malik, M.F. and Mahmood, T., 2022. Intraocular Pressure Control after Trabeculectomy with Adjunctive Use of Mitomycin-C versus Bevacizumab: A Hospital Based Study. Pakistan Journal of Ophthalmology38(1).
  3. Occelli, L.M. and Petersen-Jones, S.M., 2022. Large Animal Models of Retinitis Pigmentosa in Therapy Development and Preclinical Testing. In Retinitis Pigmentosa (pp. 233-248). New York, NY: Springer US.
  1. Islam, M.N., 2021. Filtration surgery and glaucoma drainage devices in PACG. Primary Angle Closure Glaucoma (PACG) A Logical Approach in Management, pp.87-99.
  2. Islam, M.N., 2021. Filtration surgery and glaucoma drainage devices in PACG. Primary Angle Closure Glaucoma (PACG) A Logical Approach in Management, pp.87-99.
  3. Yazdani, S., Pakravan, M., Gerami, E., Doozandeh, A., Esfandiari, H. and Sharifipour, F., 2022. Trabeculotomy versus combined trabeculotomy-trabeculectomy for management of primary congenital glaucoma. Journal of Glaucoma31(5), pp.346-350.
  4. Mansour, S.E., Browning, D.J., Wong, K., Flynn Jr, H.W. and Bhavsar, A.R., 2020. The evolving treatment of diabetic retinopathy. Clinical Ophthalmology, pp.653-678.
  5. Kutlutürk Karagöz, I., Allahverdiyev, A., Bağırova, M., Abamor, E.Ş. and Dinparvar, S., 2020. Current approaches in treatment of diabetic retinopathy and future perspectives. Journal of Ocular Pharmacology and Therapeutics36(7), pp.487-496.
  6. Liu, Y. and Wu, N., 2021. Progress of nanotechnology in diabetic retinopathy treatment. International journal of nanomedicine, pp.1391-1403.
  7. Striglia, E., Caccioppo, A., Castellino, N., Reibaldi, M. and Porta, M., 2020. Emerging drugs for the treatment of diabetic retinopathy. Expert Opinion on Emerging Drugs25(3), pp.261-271.
  8. Zhang, Z., Amegbor, P.M., Sigsgaard, T. and Sabel, C.E., 2022. Assessing the association between urban features and human physiological stress response using wearable sensors in different urban contexts. Health & Place, 78, p.102924.
  9. van Dammen, L., Finseth, T.T., McCurdy, B.H., Barnett, N.P., Conrady, R.A., Leach, A.G., Deick, A.F., Van Steenis, A.L., Gardner, R., Smith, B.L. and Kay, A., 2022. Evoking stress reactivity in virtual reality: A systematic review and meta-analysis. Neuroscience & Biobehavioral Reviews, 138, p.104709.
  10. Acevedo, C.M.D., Gómez, J.K.C. and Rojas, C.A.A., 2021. Academic stress detection on university students during COVID-19 outbreak by using an electronic nose and the galvanic skin response. Biomedical Signal Processing and Control, 68, p.102756.
  11. Yang, X., McCoy, E., Anaya-Boig, E., Avila-Palencia, I., Brand, C., Carrasco-Turigas, G., Dons, E., Gerike, R., Goetschi, T., Nieuwenhuijsen, M. and Orjuela, J.P., 2021. The effects of traveling in different transport modes on galvanic skin response (GSR) as a measure of stress: An observational study. Environment International, 156, p.106764.
  1. Yang, X., Orjuela, J.P., McCoy, E., Vich, G., Anaya-Boig, E., Avila-Palencia, I., Brand, C., Carrasco-Turigas, G., Dons, E., Gerike, R. and Götschi, T., 2022. The impact of black carbon (BC) on mode-specific galvanic skin response (GSR) as a measure of stress in urban environments. Environmental research, 214, p.114083.
  2. Sharma, S., Singh, G. and Sharma, M., 2021. A comprehensive review and analysis of supervised-learning and soft computing techniques for stress diagnosis in humans. Computers in Biology and Medicine, 134, p.104450.