advertisement
3.9 Pathophysiology (191)
Showing records 1 to 25
Display all abstracts in classification 3.9 Pathophysiology
Search within classification 3.9 Pathophysiology84756 Potential mechanisms of retinal ganglion cell type-specific vulnerability in glaucoma
Wang AY
Clinical and Experimental Optometry 2020; 103: 562-571
84627 Role of Fibronectin in Primary Open Angle Glaucoma
Faralli JA
Cells 2019; 8:
84908 Involvement of regulated necrosis in blinding diseases: Focus on necroptosis and ferroptosis
Peng JJ
Experimental Eye Research 2020; 191: 107922
85211 Connective Tissue Remodeling in Myopia and its Potential Role in Increasing Risk of Glaucoma
Grytz R
Current opinion in biomedical engineering 2020; 15: 40-50
84780 Involvement of free radical-mediated oxidation in the pathogenesis of pseudoexfoliation syndrome detected based on specific hydroxylinoleate isomers
Umeno A
Free Radical Biology and-Medicine 2020; 147: 61-68
84283 The Probable Mechanism of Traumatic Angle Recession and Cyclodialysis
Pujari A
Journal of Glaucoma 2020; 29: 67-70
84909 Nuclear factor-kappa beta signaling is required for transforming growth factor Beta-2 induced ocular hypertension
Hernandez H
Experimental Eye Research 2020; 191: 107920
85009 Ocular Accommodation, Intraocular Pressure, Development of Myopia and Glaucoma: Role of Ciliary Muscle, Choroid and Metabolism
Aggarwala KRG
Medical hypothesis, discovery and innovation in ophthalmology 2020; 9: 66-70
84590 Under pressure: Cerebrospinal fluid contribution to the physiological homeostasis of the eye
Mirra S
Seminars in Cell and Developmental Biology 2019; 0:
84606 Intracranial pressure modulates aqueous humour dynamics of the eye
Ficarrotta KR
Journal of Physiology 2020; 598: 403-413
84756 Potential mechanisms of retinal ganglion cell type-specific vulnerability in glaucoma
Wang AY
Clinical and Experimental Optometry 2020; 103: 562-571
84293 Correlating Structural and Functional Damage in Glaucoma
Torres LA
Journal of Glaucoma 2019; 28: 1079-1085
84764 TRPC5 regulates axonal outgrowth in developing retinal ganglion cells
Oda M
Laboratory Investigation 2020; 100: 297-310
84691 The Influence of Translaminar Pressure Gradient and Intracranial Pressure in Glaucoma: A Review
Price DA
Journal of Glaucoma 2020; 29: 141-146
84277 Glaucoma After Corneal Trauma or Surgery-A Rapid, Inflammatory, IOP-Independent Pathway
Dohlman CH
Cornea 2019; 38: 1589-1594
84914 Vitreous albumin redox state in open-angle glaucoma patients and controls: a pilot study
Schwab C
International Ophthalmology 2020; 0:
85014 A Theoretical Approach for the Electrochemical Characterization of Ciliary Epithelium
Sacco R
Life (Basel, Switzerland) 2020; 10:
84623 The role of intracranial pressure in glaucoma and therapeutic implications
Baneke AJ
Eye 2020; 34: 178-191
85210 The Role of Autophagy in Glaucomatous Optic Neuropathy
Adornetto A
Frontiers in cell and developmental biology 2020; 8: 121
85159 Pathogenic roles of retinal glia in glaucoma
Shinozaki Y
Nippon yakurigaku zasshi 2020; 155: 87-92
85004 Elevated Intraocular Pressure Causes Abnormal Reactivity of Mouse Retinal Arterioles
Gericke A
Oxidative medicine and cellular longevity 2019; 2019: 9736047
84633 Elevated pressure influences relative distribution of segmental regions of the trabecular meshwork
Vranka JA
Experimental Eye Research 2020; 190: 107888
85051 Vps35 Deficiency Impairs Cdk5/p35 Degradation and Promotes the Hyperphosphorylation of Tau Protein in Retinal Ganglion Cells
Gao L
Investigative Ophthalmology and Visual Science 2020; 61: 1
85214 Retinal correlates of psychiatric disorders
Almonte MT
Therapeutic advances in chronic disease 2020; 11: 2040622320905215
85158 Expression changes in microRNA in the retina of retinal degenerative diseases
Sakamoto K
Nippon yakurigaku zasshi 2020; 155: 81-86
