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Human cardiovascular responses to positive pressure breathing with counter pressureCarstairs, Rachael Caroline January 1999 (has links)
No description available.
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Quantification of regional pulmonary blood flow parameters via multidetector-row CT: evaluation of vascular-based phenotypes of COPDAlford, Sara 01 May 2010 (has links)
Emphysema, a subset of COPD, occurs due to an abnormal inflammatory response to noxious gases or particles leading an influx of immunologic cells. Recent studies have demonstrated endothelial dysfunction in COPD subjects and are suggestive of a vascular phenotype present in COPD that is not fully characterized. We hypothesize that processes affecting the pulmonary vasculature lead to early changes important in the pathogenesis of COPD. This work focuses on the use of multidetector-row computed tomography (MDCT)-based measures of pulmonary blood flow (PBF), mean transit time (MTT) and pulmonary vascular volume (TPVV) to gain new insights into vasculature-related changes present in COPD. As a precursor to using perfusion MDCT imaging to phenotype lung disease, we demonstrated good regional correlation of PBF measurements obtained with MDCT imaging and fluorescent microspheres (FMS) at a FMS piece size resolution of 1.9 cm3 and regional volume level of 8-10 cm3. Additionally, we developed an ex vivo perfusion system, and applied quantitative image analysis techniques to study the lung preparation's stability over 120 minutes. We further validated CT-based PBF and MTT measurements by demonstrating physiologically appropriate responses to a range of flow rates with this new system. Finally, quantitative MDCT-based measurements were used to characterize a novel phenotype of emphysema and test hypotheses regarding vasculature-related changes in smokers and COPD subjects. We demonstrated increased heterogeneity in regional MTT and PBF measurements in smokers with preclinical emphysema compared with smokers with normal lung function and imaging studies and nonsmokers. This data is supportive of the notion that inflammatory-based vascular responses to hypoxia are occurring in smokers susceptible to COPD, but are successfully blocked in smokers without signs of emphysema. A new CT-based measure, TPVV, was studied and we demonstrate its association with total lung volume and body size metrics. TPVV measurements correlated with measures of COPD severity. A trend linking increased TPVV with increased endothelial dysfunction was observed, suggesting that pathological changes of COPD have an effect on the pulmonary vasculature. This work demonstrates the importance of functional information that can compliment structural, anatomical information to answer questions based on the lung physiology and pathological disease processes.
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ECTによる肺血流分布の測定TORIZUKA, Kanji, FUJITA, Toru, MINATO, Kotaro, MUKAI, Takao, ISHII, Yasushi, TODO, Yoshiro, ITOH, Harumi, MAEDA, Hisatoshi, 鳥塚, 莞爾, 藤田, 透, 湊, 小太郎, 向井, 孝夫, 石井, 靖, 藤堂, 義郎, 伊藤, 春海, 前田, 尚利 05 1900 (has links)
No description available.
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Endogenous Nitric Oxide Production and Pulmonary Blood Flow : during different experimental lung conditionsNilsson, Manja January 2011 (has links)
Nitric oxide (NO) is an important regulator of pulmonary blood flow and attenuates hypoxic pulmonary vasoconstriction (HPV). Nitric oxide is synthesized enzymatically in a number of tissues, including the lungs, and can also be generated from reduction of nitrite during hypoxia and acidosis. Inhaled nitric oxide (INO) is a selective pulmonary vasodilator, with no effects on systemic arterial blood pressure due to inactivation by hemoglobin in the blood. INO has distant effects both within the lungs and in other organs, since NO can be transported to remote tissues bound to proteins, or as more stable molecules of nitrite and nitrate. In healthy pigs, INO causes vasoconstriction and down regulation of endogenous NO production in lung regions not reached by INO, and predominantly so in hypoxic lung regions, i.e. augmentation of HPV. In this thesis, distant effects of INO in pigs with endotoxemic- and lavage-induced lung injuries were studied. INO increased the NO production in lung regions not reached by INO in endotoxemic pigs, whereas endogenous NO production was unaffected in pigs with lavage-induced injury. Metabolic and/or hypercapnic acidosis frequently occurs in critically ill patients, but whether acidosis affects the endogenous pulmonary NO production is unclear. The regional NO production and blood flow in hyperoxic and hypoxic lung regions, were studied during metabolic and hypercapnic acidosis. Neither metabolic, nor hypercapnic acidosis changed the endogenous NO production in hyperoxic or hypoxic lung regions. Metabolic acidosis potentiated HPV, whereas hypercapnic acidosis transiently attenuated HPV. In conclusion, the present thesis has demonstrated that INO in experimental sepsis increases the endogenous NO production in lung regions not reached by INO, which may cause increased shunt and poor response to INO. This distant effect is not seen in lavage injuried lungs, an experimental model with less inflammation. Acidosis does not affect the endogenous pulmonary NO production in hyperoxic or hypoxic lung regions. Whereas metabolic acidosis potentiates HPV, hypercapnic acidosis transiently attenuates HPV, due to a combination of hypercapnia-induced increase in cardiac output and a probable vasodilating effect of the CO2-molecule.
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