Vascular changes in the retina in patients with chronic respiratory insufficiency
Abstract
Background/Aim. Chronic respiratory insufficiency is a pathological state which occurs as a result of respiratory system inability to maintain normal gas exchange between the outside air and circulating blood. For the purposes of human organism’s proper functioning, it is necessary that a certain amount of air in the lungs comes into contact with a certain amount of blood within a unit of time, so that an adequate hemoglobin oxygenation could be achieved. Then, hemoglobin from erythrocytes in the blood supply delivers oxygen to all the tissues and cells of the body including the eye. Direct impact of hypoxemia and hypercapnia on the wall of arterioles, venules and capillaries results in a severe vasodilatation along with the increased permeability of the walls causing clinically evident changes in the retina. The aim of this study was to determine the degree of ocular changes in retina with patients suffering from chronic respiratory insufficiency. Methods. A prospective study was conducted on 80 patients, 40 patients with respiratory failure and 40 patients with chronic obstructive pulmonary disease an and bronchial asthma (the control group). In all the patients direct and indirect ophthalmoscopy and fluoresceine angiography was performed. Clinically visible fundus and retina changes in patients suffering from chronic respiratory failure were categorized as mild (dilatation and retinal veins and arteries tortosion up to the mid-periphery), moderate (retinal hemorrhage) and severe (optic nerve edema, macular edema, superficial and deep retinal hemorrhages and venous occlusion). Results. In the patients suffering from respiratory insufficiency the changes in retinal blood vessels were found [in 18 (45%) mild, in 13 (32.5%) moderate, and in 9 (22%) severe], while in the patients with chronic obstructive pulmonary disease and bronchial asthma (without respiratory insufficiency) no changes were recognized. Conclusion. The results of this study indicate the need for ophthalmologic examination in patients with chronic respiratory insufficiency. It is important to recognize, identify and quantify the changes on retinal blood vessels which are clinically significant. It is necessary to provide their monitoring and to prescribe proper therapeutic treatment in order to preserve visual functions.
References
Bogdanovic M. Chronic obstructive insufficiency In: Stefanovic S, editor. Internal medicine. Belgrade: Medicinska knjiga; 1994. p. 523−32. (Serbian)
Durie O, Sekulic S. Disease organs for respiration. In: Manojlovic D, editor. Internal medicine. Belgrade: Zavod za udzbenike i nastavna sredstva; 1998. p. 335−46. (Serbian)
Miladinovic D. Pharmacotherapy chronical respiratory failure and chronic lungs heart. In: Varagic V, Stevanovic M, editors. Pharmacotherapy in pulmology. Belgrade: Elit Medica; 1998. p. 407−23. (Serbian)
Sato T, Oku H, Tsuruma K, Katsumura K, Shimazawa M, Hara H, et al. Effect of hypoxia on susceptibility of RGC-5 cells to ni-tric oxide. Invest Ophtalmol Vis Sci 2010; 51(5): 2575−86.
Gidday JM, Maceren RG, Shah AR, Meier JA, Zhu Y. KATP channels mediate adenosine-induced hyperemia in retina. In-vest Ophtalmol Vis Sci 1996; 37(13): 2624−33.
Hill SN. Chronic respiratory failure and noninvasive ventila-tion. In: Baum GL, editor. Textbook of pulmonary diseases. Philadelphia: Lipincott-Raven; 1998. p. 969−86.
Mitic Milikic M. Chronical respiratory failure. In: Manojlovic D, editor. Internal medicine. Belgrade: Zavod za udzbenike i nas-tavna sredstva; 2009. p. 494−505. (Serbian)
Economopoulou M, Langer HF, Celeste A, Orlova VV, Choi EY, Ma M, et al. Histone H2AX is integral to hypoxia-driven neo-vascularization. Nat Med 2009; 15(5): 553−8.
Fisher OA, Romanchikov IuN, Ignat’eva LP. Effect of local reva-sularization of choroid on ocular tissues and lipid peroxidation in experimental atherosclerotic chorioretinopathy. West Of-talmol 1998; 114(4): 32−5.
Alm A. Ocular circulation. In: Hart WM, editor. Adler's physi-ology od the eye. St Louis, USA: Mosby Year Book; 2011. p. 198−227.
Duker J, Weiter II. Ocular circulation. In: Tasman W, Jaeger EA, editors. Duane's foundations of clinical ophtamology. New York: JB Lippincott Co; 1991. p. 1−34.
Tayyari F, Venkataramen ST, Gilmore ED, Wong T, Fisher J, Hud-son C. The relationship between retinal vascular reactivity and arteriolar diameter in response to metyabolic provocation. In-vest Ophthalmol Vis Sci 2009; 50(10): 4814−21.
Thylefors J, Piitulainen E, Havelius U. Dark adaptation during sys-temic hypoxia induced by chronic respiratory insufficiency In-vest Ophthalmol Vis Sci 2009; 50(3): 1307−12.
Chen B, Guber A, Marom Z. Advance long-term oxygen therapy. RT Intern 1995; 4(1): 55−60.
Schweitzer D, Hammer M, Kraft J, Thamm E, Königsdörffer E, Strobel J. In vivo measurement of the oxygen saturation of retinal vessels in healthy volunteers. IEEE Trans Biomed Eng 1999; 46(12): 1454−65.
Dunskyj MJ, Eriksen E, Dore CJ, Kohner EM. Autoregulation in the human retinal circulation: Assessment using isometric ex-ercise. Laser doppler velocimetry and comuter-assisted image analysis. London: Raven Press; 1996.
Liu X, Wang W, Wang AR, Ning Q, Luo XP. Pathogenesis of retinal neovascularization in a rat model of oxygen fluctua-tions-induced retinopathy. Zhonghua Er Ke Za Zhi 2007; 45(1): 7−13. (Chinese)
Fulton AB, Akula JD, Mocko JA, Hansen RM, Benador IY, Beck SC, et al. Retinal degenerative and hypoxic ischemic disease. Doc Ophthalmol 2009; 118(1): 55−61.
Grippi MA. Pulmonary pathophysiology. Philadelphia: JB Lip-pincott Co; 1998.
Sekulić S. Pulmonary diseases. Belgrade: Elit Medica; 2009. p. 373−84.
Slavkovic V. Pulmonary function. In: Stefanovic S, editor. Internal medicine. Belgrade: Medicinska knjiga; 1994. p. 454−9. (Serbian)
Mitrouska I, Tzanakis N, Siafakas NM. Oxygen therapy in chronic obstructive pulmonary disease. Eur Respir Mon 2006; 11(38): 302−12.
Venkataraman ST, Hudson C, Fisher JA, Rodrigues L, Mardimae A, Flanagan JG. Retinal arteriolar and capillary vascular reactivity in response to isoxic hypercapnia. Exp Eye Res 2008; 87(6): 535−42.
Williams CD, Rizzolo LJ. Remodeling of functional complexes during the development of the outer blood reinal barrier. Anat Rec 1997; 249(3): 380−8.
Zeng XX, Ng YK, Ling EA. Labelling of retinal microglial cells following an intravenose injection of a fluorescent dye into rats of different ages. J Anat 2000; 196(Pt 2): 173−9.