eprintid: 1473208 rev_number: 50 eprint_status: archive userid: 608 dir: disk0/01/47/32/08 datestamp: 2016-01-28 12:09:57 lastmod: 2020-02-12 21:21:56 status_changed: 2016-01-28 12:09:57 type: thesis metadata_visibility: show creators_name: Agrawal, R title: Cellular imaging and assessment of ocular flow dynamics ispublished: unpub divisions: UCL divisions: A01 divisions: B02 divisions: C07 divisions: D08 abstract: Diabetic retinopathy (DR), age related macular degneration (AMD) and uveitis are potentially bliding disorders associated with microvascular complication and inflammation. Alterations in the blood flow can lead to visual loss in patients with DR; however, the specific mechanism is still unclear with contradictory reports of decreased or increased blood flow. There is now established role of inflammation in AMD; however there is a lack of a good model to demonstrate cellular and vascular changes in AMD and uveitis. Currently, it is uncertain if early visual deficits in DR are caused by vascular compromise or other non-vascular factors. Using advanced non invasive vascular image analysis, retinal vascular calibers and choroidal vasculature has been objectively quantified. Along with retinal vascular caliber changes, blood components such as leukocytes, erythrocytes and platelets are thought to be involved in the control of circulatory processes by numerous mechanisms. Qualitative and quantitative assessment of leukocyte and erythrocyte dynamics in vitro and in vivo in the retinal and choroidal circulation can provide additional insight into the disease mechanism and severity in DR, AMD and uveitis. Using the Ins2Akita (Akita) mouse, a well established genetic model of DR, an AMD mouse model and in vitro cell dynamics, we have evaluated the flow dynamics of cells both in vivo and in vitro to propose a composite model of cellular dynamics in DR, AMD and uveitis. The immediate significance of this mechanistic study is the development of a microvascular model for DR, AMD and uveitis, and the identification of new insights into disease pathogenesis. The wider long-term significance is the potential to predict disease progression and develop a model to study treatment response to new therapeutic agents for vasoproliferative disorders. date: 2015-12-28 thesis_class: doctoral_md_only language: eng thesis_view: UCL_Thesis verified: verified_manual elements_id: 1093990 lyricists_name: Agrawal, Rupesh lyricists_id: RAGRA49 actors_name: Agrawal, Rupesh actors_name: Mackay, Naomi actors_id: RAGRA49 actors_id: NSDMA44 actors_role: owner actors_role: impersonator full_text_status: none pages: 209 institution: UCL (University College London) department: Institute of Ophthalmology thesis_type: Doctoral citation: Agrawal, R; (2015) Cellular imaging and assessment of ocular flow dynamics. Doctoral thesis , UCL (University College London).