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1. Ocular blood flow as a clinical observation: Value, limitations and data analysis

   Harris, A. (January 2020, Progress in retinal and eye research)

   Alterations in ocular blood flow have been identified as important risk factors for the onset and progression of numerous diseases of the eye. In particular, several population-based and longitudinal-based studies have provided compelling evidence of hemodynamic biomarkers as independent risk factors for ocular disease throughout several different geographic regions. Despite this evidence, the relative contribution of blood flow to ocular physiology and pathology in synergy with other risk factors and comorbidities (e.g., age, gender, race, diabetes and hypertension) remains uncertain. There is currently no gold standard for assessing all relevant vascular beds in the eye, and the heterogeneous vascular biomarkers derived from multiple ocular imaging technologies are non-interchangeable and difficult to interpret as a whole. As a result of these disease complexities and imaging limitations, standard statistical methods often yield inconsistent results across studies and are unable to quantify or explain a patient's overall risk for ocular disease. Combining mathematical modeling with artificial intelligence holds great promise for advancing data analysis in ophthalmology and enabling individualized risk assessment from diverse, multi-input clinical and demographic biomarkers. Mechanism-driven mathematical modeling makes virtual laboratories available to investigate pathogenic mechanisms, advance diagnostic ability and improve disease management. Artificial intelligence provides a novel method for utilizing a vast amount of data from a wide range of patient types to diagnose and monitor ocular disease. This article reviews the state of the art and major unanswered questions related to ocular vascular anatomy and physiology, ocular imaging techniques, clinical findings in glaucoma and other eye diseases, and mechanistic modeling predictions, while laying a path for integrating clinical observations with mathematical models and artificial intelligence. Viable alternatives for integrated data analysis are proposed that aim to overcome the limitations of standard statistical approaches and enable individually tailored precision medicine in ophthalmology. 

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2. Ocular blood flow as a clinical observation: Value, limitations and data analysis

   Harris, A. (January 2020, Progress in retinal and eye research)

   Alterations in ocular blood flow have been identified as important risk factors for the onset and progression of numerous diseases of the eye. In particular, several population-based and longitudinal-based studies have provided compelling evidence of hemodynamic biomarkers as independent risk factors for ocular disease throughout several different geographic regions. Despite this evidence, the relative contribution of blood flow to ocular physiology and pathology in synergy with other risk factors and comorbidities (e.g., age, gender, race, diabetes and hypertension) remains uncertain. There is currently no gold standard for assessing all relevant vascular beds in the eye, and the heterogeneous vascular biomarkers derived from multiple ocular imaging technologies are non-interchangeable and difficult to interpret as a whole. As a result of these disease complexities and imaging limitations, standard statistical methods often yield inconsistent results across studies and are unable to quantify or explain a patient's overall risk for ocular disease. Combining mathematical modeling with artificial intelligence holds great promise for advancing data analysis in ophthalmology and enabling individualized risk assessment from diverse, multi-input clinical and demographic biomarkers. Mechanism-driven mathematical modeling makes virtual laboratories available to investigate pathogenic mechanisms, advance diagnostic ability and improve disease management. Artificial intelligence provides a novel method for utilizing a vast amount of data from a wide range of patient types to diagnose and monitor ocular disease. This article reviews the state of the art and major unanswered questions related to ocular vascular anatomy and physiology, ocular imaging techniques, clinical findings in glaucoma and other eye diseases, and mechanistic modeling predictions, while laying a path for integrating clinical observations with mathematical models and artificial intelligence. Viable alternatives for integrated data analysis are proposed that aim to overcome the limitations of standard statistical approaches and enable individually tailored precision medicine in ophthalmology. 

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3. Selenium Deprivation Alters Cytoskeletal Structure in Human Umbilical Vein Endothelial Cells (HUVECS)

   Taranto, Adrian; Hurt, Jalen; Bradford, David; Hines, Jaden; Davis, Brendon; Smith, Alexcia; Battles, Kaela; Patterson, Sequan; Adusei-Danso, Felix; Williams, Emmanuel (March 2023, Novel research in sciences)

   Aging and the loss of functional reserve capacity is an intrinsic feature of life driven by various factors including genetics, lifestyle, and nutrition. Nutrient signaling has been shown to modulate the onset, progression, and/or delay of many age-associated diseases including cardiovascular disease and neurodegenerative decline. While glycemic and lipid flux have been linked to the premature appearance of in vitro biomarkers of aging, the role of trace metals in age-associated cellular changes remain less clear. The trace metal Selenium (Se) is an essential trace mineral that supports many bodily processes including free radical scavenging, thyroid function, and maintenance of cognitive ability. Our research focused on the potential cellular changes in Human Umbilical Vascular Endothelial Cells (HUVECs) in response to Se deprivation. Exposed to a 48-hour continuous reduced Se exposure, we observed a reduced f-actin protein and gene expression. Interestingly, we observed a compensatory increase in the intermediate filament vimentin, which suggest that Se may have an important role in cytoskeletal maintenance and rearrangement. Keywords: Selenium; Endothelial; Oxidative stress; Vimentin; Actin; Nutrients; Aging 

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4. Transcorneal electrical stimulation restores DNA methylation changes in retinal degeneration

   https://doi.org/10.3389/fnmol.2024.1484964  

   Tew, Ben Yi; Gooden, Gerald C; Lo, Pei-An; Pollalis, Dimitrios; Ebright, Brandon; Kalfa, Alex J; Gonzalez-Calle, Alejandra; Thomas, Biju; Buckley, David N; Simon, Thomas; et al (December 2024, Frontiers in Molecular Neuroscience)

   BackgroundRetinal degeneration is a major cause of irreversible blindness. Stimulation with controlled low-level electrical fields, such as transcorneal electrical stimulation (TES), has recently been postulated as a therapeutic strategy. With promising results, there is a need for detailed molecular characterization of the therapeutic effects of TES. MethodsControlled, non-invasive TES was delivered using a custom contact lens electrode to the retinas of Royal College of Surgeons (RCS) rats, a model of retinal degeneration. DNA methylation in the retina, brain and cell-free DNA in plasma was assessed by reduced representation bisulfite sequencing (RRBS) and gene expression by RNA sequencing. ResultsTES induced DNA methylation and gene expression changes implicated in neuroprotection in the retina of RCS rats. We devised an epigenomic-based retinal health score, derived from DNA methylation changes observed with disease progression in RCS rats, and showed that TES improved the epigenomic health of the retina. TES also induced DNA methylation changes in the superior colliculus: the brain which is involved in integrating visual signaling. Lastly, we demonstrated that TES-induced retinal DNA methylation changes were detectable in cell-free DNA derived from plasma. ConclusionTES induced DNA methylation changes with therapeutic effects, which can be measured in circulation. Based on these changes, we were able to devise a liquid biopsy biomarker for retinal health. These findings shed light on the therapeutic potential and molecular underpinnings of TES, and provide a foundation for the further development of TES to improve the retinal health of patients with degenerative eye diseases. 

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5. Accurate flow in augmented networks (AFAN): an approach to generating three-dimensional biomimetic microfluidic networks with controlled flow

   https://doi.org/10.1039/C8AY01798K  

   Guo, Jiaming; Keller, Keely A.; Govyadinov, Pavel; Ruchhoeft, Paul; Slater, John H.; Mayerich, David (January 2019, Analytical Methods)

   In vivo , microvasculature provides oxygen, nutrients, and soluble factors necessary for cell survival and function. The highly tortuous, densely-packed, and interconnected three-dimensional (3D) architecture of microvasculature ensures that cells receive these crucial components. The ability to duplicate microvascular architecture in tissue-engineered models could provide a means to generate large-volume constructs as well as advanced microphysiological systems. Similarly, the ability to induce realistic flow in engineered microvasculature is crucial to recapitulating in vivo -like flow and transport. Advanced biofabrication techniques are capable of generating 3D, biomimetic microfluidic networks in hydrogels, however, these models can exhibit systemic aberrations in flow due to incorrect boundary conditions. To overcome this problem, we developed an automated method for generating synthetic augmented channels that induce the desired flow properties within three-dimensional microfluidic networks. These augmented inlets and outlets enforce the appropriate boundary conditions for achieving specified flow properties and create a three-dimensional output useful for image-guided fabrication techniques to create biomimetic microvascular networks. 

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