Global ETD Search

1	Vascular mechanisms in glaucoma - a phenotype and genotypic analysis Logan, J. F. J. January 2002 (has links) No description available. 617 Ocular blood flow
2	The Impact of Tonometer Measurement Error on Ocular Pulse Amplitude and the Estimation of Pulsatile Ocular Blood Volume Somogye, Ryan January 2021 (has links) No description available. Biomedical Engineering
3	Multiscale mathematical modeling of ocular blood flow and oxygenation and their relevance to glaucoma Carichino, Lucia 14 June 2016 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / Glaucoma is a multifactorial ocular disease progressively leading to irreversible blindness. There is clear evidence of correlations between alterations in ocular hemodynamics and glaucoma; however, the mechanisms giving rise to these correlations are still elusive. The objective of this thesis is to develop mathematical models and methods to help elucidate these mechanisms. First, we develop a mathematical model that describes the deformation of ocular structures and ocular blood flow using a reduced-order fluid-structure interaction model. This model is used to investigate the relevance of mechanical and vascular factors in glaucoma. As a first step in expanding this model to higher dimensions, we propose a novel energy-based technique for coupling partial and ordinary differential equations in blood flow, using operator splitting. Next, we combine clinical data and model predictions to propose possible explanations for the increase in venous oxygen saturation in advanced glaucoma patients. We develop a computer-aided manipulation process of color Doppler images to extract novel waveform parameters to distinguish between healthy and glaucomatous individuals. The results obtained in this work suggest that: 1) the increase in resistance of the retinal microcirculation contributes to the influence of intraocular pressure on retinal hemodynamics; 2) the influence of cerebrospinal fluid pressure on retinal hemodynamics is mediated by associated changes in blood pressure; 3) the increase in venous oxygen saturation levels observed among advanced glaucoma patients depends on the value of the patients’ intraocular pressure; 4) the normalized distance between the ascending and descending limb of the ophthalmic artery velocity profile is significantly higher in glaucoma patients than in healthy individuals. fluid-structure interaction glaucoma mathematical models multiscale coupling ocular blood flow patient-specific simulations
4	Effect of Laser Iridoplasty on Pulsatile Ocular Blood Flow in Primary Angle-closure Glaucoma and Primary Angle-closure Suspects Hill, Mathieu M. 01 January 2015 (has links) Angle-closure glaucoma is a leading cause of blindness in the United States and around the world. New research has indicated that intraocular pressure is not the only risk factor associated with glaucomatous optic neuropathy. In recent years, a vascular deregulation in ocular blood flow has been considered a possible risk factor in glaucoma. A laser peripheral iridoplasty is a standard treatment option in non-pupillary block angle-closure glaucoma. The present study employed a secondary retrospective design and utilized patient’s data from an ophthalmologist’s practice. The purpose of this study was to examine the effect of laser peripheral iridoplasty on pulsatile ocular blood flow in primary angle-closure glaucoma and primary angle-closure suspects. A sample of 30 eyes from 17 patients was analyzed for this study. A significant increase in pulsatile ocular blood flow was found among primary angle-closure suspects. Additional data analysis was performed through SPSS software to examine the effect on these variables by age, sex and medical history as a total sample and in each group. Primary angle-closure suspects who were 51-60 years old showed a significant increase in intraocular pressure after laser treatment, however, primary angle-closure glaucoma patients who were 71-80 years old showed a significant decrease in intraocular pressure. Furthermore, a significant increase in pulsatile ocular blood flow was found in female subjects among primary angle-closure suspects, supporting the need for gender medicine research. Lastly, the pulsatile ocular blood flow increased significantly among primary angle-closure suspects who were also suffering from cardiovascular disease. Among primary angle-closure glaucoma patients who were suffering from both cardiovascular disease and diabetes mellitus, a significant decrease in intraocular pressure was observed. glaucoma angle-closure glaucoma pulsatile ocular blood flow laser peripheral iridoplasty
5	Amplitude de pulso ocular em pacientes com hipertensão arterial sistêmica / Ocular pulse amplitude in patients with glaucoma and hypertension Gradvohl, Hissa Tavares de Lima 25 April 2012 (has links) Objetivo: Avaliar a amplitude de pulso ocular (APO) em pacientes com hipertensão arterial sistêmica, comparando com o grupo controle, e eventuais influências da espessura central da córnea e do comprimento axial (COMPRaxial) do olho na APO. Método: Foram examinados 152 olhos de 76 pacientes com hipertensão arterial sistêmica e 136 olhos de 68 indivíduos que compuseram o grupo controle. Todas as medidas foram tomadas pelo mesmo examinador, no período das 7 às 10h da manhã, na seguinte ordem: pressão arterial sistêmica, tonometria de contorno dinâmico, COMPRaxial e paquimetria (PAQ). A análise estatística foi realizada utilizando-se o teste t para médias de dados pareados e, para as correlações, os coeficientes de Pearson ou o de Spearman. Considerou-se o nível de significância de 5%. Resultados: A APO média dos olhos direitos dos pacientes com hipertensão arterial sistêmica foi 2,10 (+/- 0.9 mmHg) e a dos olhos esquerdos foi 2,03 (+/-0,828 mmHg). A PAQ média dos olhos direitos foi 532.2 mµ (+/- 39 mµ), e a dos olhos esquerdos 532.1 mµ (+/- 36.5 mµ), não influenciando a APO. A variável COMPRaxial para o olho direito (OD) apresentou média de 23,44 mm (+/- 1.477 mm) e para o olho esquerdo (OE) foi de 23.343 em média (+/- 1,32 mm). Houve significância estatística quando estudada a influência do COMPRaxial sobre a APO, demonstrando correlação inversamente proporcional. A média da APO dos controles foi de 2,10 (+/- 0.9 mmHg) e para o OD e OE média de 2,03 (+/-0,828 mmHg). Quando comparados os valores médios da APO dos casos e controles, a diferença foi estatisticamente significante, sendo os valores dos controles maiores do que os encontrados nos pacientes com hipertensão arterial sistêmica (p <0 ,001). Constatou-se que existe diferença entre caso e controle, tanto para o OD quanto para o OE. Conclusões: O valor médio de APO foi menor nos pacientes com hipertensão arterial sistêmica do que nos controles; a APO não foi influenciada pela espessura central da córnea; e olhos com maior COMPRaxial apresentaram APO menor / Objective: The objectives of this study were to assess the ocular pulse amplitude (OPA) in patients with hypertension, compared with control group and to evaluate possible influences of central corneal thickness and axial length of eye in OPA. Method: We evaluated 152 eyes of 76 patients with hypertension and 136 eyes of 68 individuals who comprised the control group. All measurements were made by the same examiner in the period of 7 am and 10 am, in following order: blood pressure, dynamic contour tonometry, axial length and pachymetry. Statistical analysis was performed using the t test for paired data and averages for correlations, the Pearson correlation coefficients of Spearman. Considered the significance level of 5%. Results: The average OPA in right eyes of patients with hypertension was 2.10 (standard deviation (SD) 0.9 mmHg) and in left eyes was 2.03 (SD =0.828 mmHg). The average pachymetry of right eyes was 532.2 mµ (+/- 39 mµ); and for left eyes was 53.1 mµ ( +/-36.5 mµ). The variable diameter axial in right eye showed an average of 23.44 mm (+/- 1.477 mm); for the left eye 23,343 mm (+/- 1.32). There was statistical significance when studied the influence of the axial diameter of OPA, with inverse correlation. The average of controls OPA was presented mean 2.10 (+/- 0.9 mmHg) for the right eye and the left mean 2.03 (+/- 0.828 mmHg). When comparing the mean values of OPA in cases and controls the difference was statistically significant, the values of the controls are larger those found in patients with hypertension (p<0,001), so it was found difference between cases and controls, both for the right and left eye. Conclusions: The mean OPA was lower in patients with hypertension than in controls, the OPA was not influenced by central corneal thickness, and eyes with greater axial length showed lower OPA Amplitude de pulso ocular Arterial hypertension Fluxo sanguíneo ocular Glaucoma Glaucoma Hipertensão arterial sistémica Ocular blood flow Ocular pulse amplitud Pascal tonometer Tonômetro de Pascal
6	Amplitude de pulso ocular em pacientes com hipertensão arterial sistêmica / Ocular pulse amplitude in patients with glaucoma and hypertension Hissa Tavares de Lima Gradvohl 25 April 2012 (has links) Objetivo: Avaliar a amplitude de pulso ocular (APO) em pacientes com hipertensão arterial sistêmica, comparando com o grupo controle, e eventuais influências da espessura central da córnea e do comprimento axial (COMPRaxial) do olho na APO. Método: Foram examinados 152 olhos de 76 pacientes com hipertensão arterial sistêmica e 136 olhos de 68 indivíduos que compuseram o grupo controle. Todas as medidas foram tomadas pelo mesmo examinador, no período das 7 às 10h da manhã, na seguinte ordem: pressão arterial sistêmica, tonometria de contorno dinâmico, COMPRaxial e paquimetria (PAQ). A análise estatística foi realizada utilizando-se o teste t para médias de dados pareados e, para as correlações, os coeficientes de Pearson ou o de Spearman. Considerou-se o nível de significância de 5%. Resultados: A APO média dos olhos direitos dos pacientes com hipertensão arterial sistêmica foi 2,10 (+/- 0.9 mmHg) e a dos olhos esquerdos foi 2,03 (+/-0,828 mmHg). A PAQ média dos olhos direitos foi 532.2 mµ (+/- 39 mµ), e a dos olhos esquerdos 532.1 mµ (+/- 36.5 mµ), não influenciando a APO. A variável COMPRaxial para o olho direito (OD) apresentou média de 23,44 mm (+/- 1.477 mm) e para o olho esquerdo (OE) foi de 23.343 em média (+/- 1,32 mm). Houve significância estatística quando estudada a influência do COMPRaxial sobre a APO, demonstrando correlação inversamente proporcional. A média da APO dos controles foi de 2,10 (+/- 0.9 mmHg) e para o OD e OE média de 2,03 (+/-0,828 mmHg). Quando comparados os valores médios da APO dos casos e controles, a diferença foi estatisticamente significante, sendo os valores dos controles maiores do que os encontrados nos pacientes com hipertensão arterial sistêmica (p <0 ,001). Constatou-se que existe diferença entre caso e controle, tanto para o OD quanto para o OE. Conclusões: O valor médio de APO foi menor nos pacientes com hipertensão arterial sistêmica do que nos controles; a APO não foi influenciada pela espessura central da córnea; e olhos com maior COMPRaxial apresentaram APO menor / Objective: The objectives of this study were to assess the ocular pulse amplitude (OPA) in patients with hypertension, compared with control group and to evaluate possible influences of central corneal thickness and axial length of eye in OPA. Method: We evaluated 152 eyes of 76 patients with hypertension and 136 eyes of 68 individuals who comprised the control group. All measurements were made by the same examiner in the period of 7 am and 10 am, in following order: blood pressure, dynamic contour tonometry, axial length and pachymetry. Statistical analysis was performed using the t test for paired data and averages for correlations, the Pearson correlation coefficients of Spearman. Considered the significance level of 5%. Results: The average OPA in right eyes of patients with hypertension was 2.10 (standard deviation (SD) 0.9 mmHg) and in left eyes was 2.03 (SD =0.828 mmHg). The average pachymetry of right eyes was 532.2 mµ (+/- 39 mµ); and for left eyes was 53.1 mµ ( +/-36.5 mµ). The variable diameter axial in right eye showed an average of 23.44 mm (+/- 1.477 mm); for the left eye 23,343 mm (+/- 1.32). There was statistical significance when studied the influence of the axial diameter of OPA, with inverse correlation. The average of controls OPA was presented mean 2.10 (+/- 0.9 mmHg) for the right eye and the left mean 2.03 (+/- 0.828 mmHg). When comparing the mean values of OPA in cases and controls the difference was statistically significant, the values of the controls are larger those found in patients with hypertension (p<0,001), so it was found difference between cases and controls, both for the right and left eye. Conclusions: The mean OPA was lower in patients with hypertension than in controls, the OPA was not influenced by central corneal thickness, and eyes with greater axial length showed lower OPA Amplitude de pulso ocular Fluxo sanguíneo ocular Glaucoma Hipertensão arterial sistémica Tonômetro de Pascal Arterial hypertension Glaucoma Ocular blood flow Ocular pulse amplitud Pascal tonometer
7	Évaluation de la régulation de l'oxygénation dans les capillaires de la tête du nerf optique suivant un effort physique dynamique Sauvageau, Patrick 08 1900 (has links) Il est généralement accepté que les lits vasculaires oculaires auraient la faculté d’autoréguler leur apport sanguin afin de contrebalancer les variations de pression de perfusion oculaire (PPO). Plusieurs études ont tenté d’évaluer ce mécanisme en mesurant les effets d’une variation de la PPO - induite par un exercice ou par une augmentation de la pression intra-oculaire (PIO) à l’aide d’une suction sclérale - sur le débit sanguin oculaire (DSO). Or, les méthodes de mesure du DSO utilisées jusqu'à maintenant présentent de nombreux désavantages et limites, ce qui rend difficile leur usage clinique. De récents développements dans le domaine des investigations non-invasives des paramètres sanguins oculaires proposent un modèle capable de mesurer en temps réel la concentration en oxygène, un autre paramètre important du métabolisme rétinien. Dans le cadre de la présente étude, ce nouveau modèle est utilisé afin de mesurer les effets d’un effort physique dynamique sur la concentration d’oxygène dans les capillaires de la tête du nerf optique (COTNO) de sujets jeunes et en santé. Six jeunes hommes non fumeurs ont participé à l’étude. L’effort physique dynamique consistait en une séance de bicyclette stationnaire de 15 minutes menant à une augmentation du pouls à 160 battements par minute. La COTNO était mesurée avant et immédiatement après la séance d’exercice. La pression artérielle (PA) et la PIO étaient mesurées ponctuellement alors que le pouls et la saturation sanguine en oxygène (SpO2) au niveau digital étaient mesurés tout au long de l’expérience. L’effort physique a entrainé une réduction de la PIO chez tous les sujets, une réduction de la COTNO chez tous les sujets sauf un tandis que la SpO2 demeura constante chez tous les sujets. Une corrélation quadratique entre les variations de la PIO et de la COTNO a pu être notée. Ces résultats suggèrent une corrélation directe entre les variations de la COTNO et celles de la PPO et de la PA. Les résultats de la présente étude suggèrent que les variations de la COTNO chez un sujet en santé suite à un effort physique dynamique pourraient représenter sa capacité à compenser un tel effort. De plus, les changements métaboliques sanguins induits par l’effort physique dynamique pourraient représenter une cause commune aux variations de la PIO et de la COTNO. / It is generally accepted that ocular vascular beds have the ability to autoregulate their blood flow to counter balance the variations in the ocular perfusion pressure (OPP). Many studies have tried to evaluate this mechanism by quantifying the effects of a variation in OPP on the ocular blood flow (OBF). This was induced by either exercise or scleral suction which increases intra-ocular pressure (IOP). However, the methods used for these measurements have many disadvantages and limitations, which deters their clinical use. Recent developments in the field of non-invasive investigation of ocular blood parameters propose a model for the measurement, in real-time, of oxygen concentration in the blood streams, another important parameter of the retinal metabolism. In the present study, this new model is used to evaluate the effects of dynamic physical efforts on the blood oxygenation in the optic nerve head capillary structures (BOONH) in young healthy subjects. Six non-smoking young men participated in the study. 15-minute sessions of stationary bicycle leading to a heart rate of 160bpm were performed as dynamic physical effort. The BOONH was measured before and immediately after the exercise. The blood pressure (BP) and the IOP were measured periodically while the heart rate and the oxygen saturation in blood (SpO2) were measured in a finger throughout the exercise. The physical effort led to a reduction of the IOP in all subjects, a decrease in the BOONH in all but one subjects and a constant SpO2 in all subjects. A quadratic correlation was observed between the variations in IOP and in BOONH. These results suggest a direct correlation between the variations in BOONH and those of the OPP and the BP. The results of the present study suggest that the variations in BOONH in a healthy subject following a physical dynamic effort could indicate his/her capacity to compensate for such an effort. Moreover, the metabolic changes in the blood due to physical dynamic efforts could be a common cause of the variations in IOP and BOONH. Oxymétrie Spectrophotométrie Exercice Débit sanguin oculaire Concentration d’oxygène Autorégulation Pression intra-oculaire Nerf optique Pression artérielle Métabolisme rétinien Oxymetry Spectrophotometry Exercise Ocular blood flow Oxygen concentration Autoregulation Intraocular pressure Optic nerve Blood pressure Retinal metabolism
8	Évaluation de la régulation de l'oxygénation dans les capillaires de la tête du nerf optique suivant un effort physique dynamique Sauvageau, Patrick 08 1900 (has links) Il est généralement accepté que les lits vasculaires oculaires auraient la faculté d’autoréguler leur apport sanguin afin de contrebalancer les variations de pression de perfusion oculaire (PPO). Plusieurs études ont tenté d’évaluer ce mécanisme en mesurant les effets d’une variation de la PPO - induite par un exercice ou par une augmentation de la pression intra-oculaire (PIO) à l’aide d’une suction sclérale - sur le débit sanguin oculaire (DSO). Or, les méthodes de mesure du DSO utilisées jusqu'à maintenant présentent de nombreux désavantages et limites, ce qui rend difficile leur usage clinique. De récents développements dans le domaine des investigations non-invasives des paramètres sanguins oculaires proposent un modèle capable de mesurer en temps réel la concentration en oxygène, un autre paramètre important du métabolisme rétinien. Dans le cadre de la présente étude, ce nouveau modèle est utilisé afin de mesurer les effets d’un effort physique dynamique sur la concentration d’oxygène dans les capillaires de la tête du nerf optique (COTNO) de sujets jeunes et en santé. Six jeunes hommes non fumeurs ont participé à l’étude. L’effort physique dynamique consistait en une séance de bicyclette stationnaire de 15 minutes menant à une augmentation du pouls à 160 battements par minute. La COTNO était mesurée avant et immédiatement après la séance d’exercice. La pression artérielle (PA) et la PIO étaient mesurées ponctuellement alors que le pouls et la saturation sanguine en oxygène (SpO2) au niveau digital étaient mesurés tout au long de l’expérience. L’effort physique a entrainé une réduction de la PIO chez tous les sujets, une réduction de la COTNO chez tous les sujets sauf un tandis que la SpO2 demeura constante chez tous les sujets. Une corrélation quadratique entre les variations de la PIO et de la COTNO a pu être notée. Ces résultats suggèrent une corrélation directe entre les variations de la COTNO et celles de la PPO et de la PA. Les résultats de la présente étude suggèrent que les variations de la COTNO chez un sujet en santé suite à un effort physique dynamique pourraient représenter sa capacité à compenser un tel effort. De plus, les changements métaboliques sanguins induits par l’effort physique dynamique pourraient représenter une cause commune aux variations de la PIO et de la COTNO. / It is generally accepted that ocular vascular beds have the ability to autoregulate their blood flow to counter balance the variations in the ocular perfusion pressure (OPP). Many studies have tried to evaluate this mechanism by quantifying the effects of a variation in OPP on the ocular blood flow (OBF). This was induced by either exercise or scleral suction which increases intra-ocular pressure (IOP). However, the methods used for these measurements have many disadvantages and limitations, which deters their clinical use. Recent developments in the field of non-invasive investigation of ocular blood parameters propose a model for the measurement, in real-time, of oxygen concentration in the blood streams, another important parameter of the retinal metabolism. In the present study, this new model is used to evaluate the effects of dynamic physical efforts on the blood oxygenation in the optic nerve head capillary structures (BOONH) in young healthy subjects. Six non-smoking young men participated in the study. 15-minute sessions of stationary bicycle leading to a heart rate of 160bpm were performed as dynamic physical effort. The BOONH was measured before and immediately after the exercise. The blood pressure (BP) and the IOP were measured periodically while the heart rate and the oxygen saturation in blood (SpO2) were measured in a finger throughout the exercise. The physical effort led to a reduction of the IOP in all subjects, a decrease in the BOONH in all but one subjects and a constant SpO2 in all subjects. A quadratic correlation was observed between the variations in IOP and in BOONH. These results suggest a direct correlation between the variations in BOONH and those of the OPP and the BP. The results of the present study suggest that the variations in BOONH in a healthy subject following a physical dynamic effort could indicate his/her capacity to compensate for such an effort. Moreover, the metabolic changes in the blood due to physical dynamic efforts could be a common cause of the variations in IOP and BOONH. Oxymétrie Spectrophotométrie Exercice Débit sanguin oculaire Concentration d’oxygène Autorégulation Pression intra-oculaire Nerf optique Pression artérielle Métabolisme rétinien Oxymetry Spectrophotometry Exercise Ocular blood flow Oxygen concentration Autoregulation Intraocular pressure Optic nerve Blood pressure Retinal metabolism

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