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Novel computational methods for image analysis and quantification using position sensitive radiation detectorsSanchez Crespo, Alejandro January 2005 (has links)
The major advantage of position sensitive radiation detector systems lies in their ability to non invasively map the regional distribution of the emitted radiation in real-time. Three of such detector systems were studied in this thesis, gamma-cameras, positron cameras and CMOS image sensors. A number of physical factors associated to these detectors degrade the qualitative and quantitative properties of the obtained images. These blurring factors could be divided into two groups. The first group consists of the general degrading factors inherent to the physical interaction processes of radiation with matter, such as scatter and attenuation processes which are common to all three detectors The second group consists of specific factors inherent to the particular radiation detection properties of the used detector which have to be separately studied for each detector system. Therefore, the aim of this thesis was devoted to the development of computational methods to enable quantitative molecular imaging in PET, SPET and in vivo patient dosimetry with CMOS image sensors. The first task was to develop a novel quantitative dual isotope method for simultaneous assessments of regional lung ventilation and perfusion using a SPET technique. This method included correction routines for photon scattering, non uniform attenuation at two different photon energies (140 and 392 keV) and organ outline. This quantitative method was validated both with phantom experiments and physiological studies on healthy subjects. The second task was to develop and clinically apply a quantitative method for tumour to background activity uptake measurements using planar mammo-scintigraphy, with partial volume compensation. The third stage was to produce several computational models to assess the spatial resolution limitations in PET from the positron range, the annihilation photon non-collineairy and the photon depth of interaction. Finally, a quantitative image processing method for a CMOS image sensor for applications in ion beam therapy dosimetry was developed. From the obtained phantom and physiological results it was concluded that the methodologies developed for the simultaneous measurement of the lung ventilation and perfusion and for the quantification of the tumour malignancy grade in breast carcinoma were both accurate. Further, the obtained models for the influence that the positron range in various human tissues, and the photon emission non-collinearity and depth of interaction have on PET image spatial resolution, could be used both to optimise future PET camera designs and spatial resolution recovery algorithms. Finally, it was shown that the proton fluence rate in a proton therapy beam could be monitored and visualised by using a simple and inexpensive CMOS image sensor.
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The Immune Response to One-Lung Ventilation : Clinical and Experimental StudiesSchilling, Thomas January 2009 (has links)
One-lung ventilation (OLV) as an established procedure during thoracic surgery may be injurious in terms of increased mechanical stress characterised by alveolar cell stretch and overdistension, increased cyclic tidal recruitment of alveolar units, compression of alveolar vessels and increased pulmonary vascular resistance. This may result in ventilation-induced lung injury with pro-inflammatory cytokine production, leukocyte recruitment and neutrophil-dependent tissue destruction. Despite the consequences of delivering the whole tidal volume (VT) to only a single lung, relatively high VT are used during OLV to maintain arterial oxygenation and carbon dioxide elimination. However, this may increase mechanical stress in the dependent lung and may aggravate alveolar injury. There is a lack of data on the alveolar immune consequences of OLV. Therefore, the present studies investigate the epithelial damage and pro-inflammatory response induced by mechanical ventilation and OLV. OLV induced pulmonary injury, but alveolar damage in the ventilated lung decreased by reduction of the tidal volume in patients scheduled for thoracic surgery (study I). The use of the volatile anaesthetic desflurane in OLV patients attenuated the OLV-induced alveolar immune response (study II). Furthermore, an experimental model of thoracic surgery was established to investigate the systemic and pulmonary consequences of OLV and thoracic surgery in comparison with the effects of conventional two-lung ventilation and spontaneous breathing. The experimental data indicate that beside the pulmonary immune response volatile anaesthetics have also modulated the plasma concentrations of cytokines during and after OLV (study III). In contrast, OLV and thoracic surgery increased the expression of pro-inflammatory mRNA in BAL cells and lung tissue samples. General anaesthesia did not affect this response (study 4). The results of the present studies indicate that OLV and thoracic surgery may be injurious to the lung tissue to a similar degree. The recruitment and activation of alveolar granulocytes characterise the alveolar damage. The administration of different anaesthetics modulates the activation of alveolar cells, specified by decreased inflammatory mediator release in subjects that receive desflurane anaesthesia, which does not affect the expression of cytokine mRNA in alveolar cells and lung tissue samples.
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La désaturation cérébrale lors d’une chirurgie thoracique : son incidence et sa corrélation avec les complications post opératoiresKazan, Roy 08 1900 (has links)
La ventilation unipulmonaire (SLV; Single Lung Ventilation) pendant les chirurgies thoraciques entraîne des altérations cardio-pulmonaires et hémodynamiques importantes. L’objectif de ce projet de recherche consiste à étudier l’impact de la SLV sur l’oxymétrie cérébrale et sa relation avec les complications post opératoires.
La première étude inclut vingt patients ayant subi une chirurgie thoracique nécessitant une SLV. L’oxymétrie a été mesurée à l’aide de l’oxymètre cérébral absolu FORESIGHTTM (CASMED, USA) afin d’étudier les changements de la saturation cérébrale absolue (SctO2) tout le long de la chirurgie. La SctO2 ainsi que les paramètres de monitorage standard (BIS, SpO2, pression sanguine, fréquence cardiaque) ont été notés à toutes les cinq minutes à partir de l’induction jusqu’au réveil. Une analyse sanguine (paO2, paCO2, Hb) a été effectuée à toutes les quinze minutes.
La deuxième étude effectuée consistait d’étudier la relation entre la désaturation cérébrale en oxygène et les complications post opératoires. Pour cette fin, les scores Clavien et SOFA mesurant l’amplitude des complications, ont été établis pour chaque patient. Les données sont présentées sous forme de moyenne et de la médiane [1er quartile, 3ème quartile; min – max].
Les vingt patients de la première étude ont montré une valeur moyenne absolue de saturation cérébrale absolue (SctO2) de 80% avant l’induction. Durant la SLV, cette valeur a chuté jusqu’à 63% et est remontée à 71% directement après extubation. Tous ces patients ont subi une désaturation durant SLV de plus que 15% comparativement à la valeur de base et 70% ont eu une désaturation de plus de 20%. La désaturation n’a pas été corrélée avec aucun des paramètres de monitorage clinique standard comme la pression artérielle, les analyses des gaz artériels, la saturation périphérique ou la PaO2.
La deuxième étude incluant trente autres patients aux vingt premiers, est venue confirmer les résultats de la première étude. De plus, une analyse de corrélation entre les valeurs minimales de SctO2 obtenues durant SLV et les complications post opératoires a été effectuée. Les patients avaient une SctO2 de base de 80%, qui a chuté jusqu’à 64% pendant la SLV pour récupérer à 71% avant la fin de la chirurgie. 82% des patients ont subi des désaturations de plus de 15% des valeurs initiales et 10% ont atteint des valeurs de SctO2 entre 45 et 55%. Les valeurs minimales de SctO2 observées durant la SLV corrélaient avec le score SOFA non respiratoire (R2=0,090, p=0,0287) ainsi qu’avec le score Clavien (R2=0,098, p=0,0201), mais ne corrélait avec aucun des paramètres cliniques standards (ex : SpO¬2, PaO2, PaCO2, Hb). En définissant une valeur seuil de SctO2=65%, le «Odds ratio» d’avoir une défaillance d’organe non respiratoire est de 2.37 (IC 95%=1,18 – 4,39, p=0,043) et d’avoir une complication classifiée supérieure à un score Clavien de 0 est de 3,19 (IC 95%=1,6 – 6,34, p=0,0272).
Les chirurgies thoraciques avec une SLV sont associées à des chutes significatives de SctO2, et les valeurs minimales de SctO2 semblent avoir une corrélation positive avec les complications post opératoires. / Single lung ventilation (SLV) during thoracic surgery causes important cardiopulmonary disturbances and numerous hemodynamic changes. The objective of this research project was to study the impact of the SLV on the cerebral oximetry values SctO2 and its relationship with postoperative complications.
Twenty patients were included in the first study undergoing thoracic surgeries with SLV. SctO2 was measured using the FORE-SIGHT™ (CASMED, USA) oximeter in order to study SctO2 changes along the surgery. SctO2 values as well as the standard monitoring parameters (BIS, SpO2, BP, HR) were recorded every 5 min starting from the induction until the awake of the patient. A blood gas analysis (paO2, paCO2, Hb) was performed every 15 min during the SLV.
The second study consisted of studying the relationship between minimal SctO2 values reached during SLV and the post-operative complications. For this, SOFA and Clavien scores were established for each patient, measuring the severity of early postoperative complications. Data are presented as mean and median [1st quartile, 3rd quartile; min – max].
Twenty patients from the first study showed a mean SctO2 baseline value of 80% before induction. During SLV, this value dropped to 63% and recovered to 71% directly after extubation. All the patients showed cerebral oxygen desaturations of more than 15% from baseline value and 70% of patients had SctO2 desaturations of more than 20%. Those désaturations did not correlate with any of the standard clinical monitoring parameters such as blood pressure, blood gas analysis, peripheral saturation or PaO2.
The second study, including thirty additional patients added to the previous twenty, came to confirm the results previously obtained. Furthermore, a correlation analysis was performed between minimal absolute SctO2 values obtained during SLV and postoperative complications. The fifty patients had a mean SctO2 baseline value of 80%, dropped to 64% during SLV and recovered to 71% before the end of the surgery. 82% of the patients had a decrease of SctO2 of more than 15% from baseline values and 10% of patients reached minimal saturation values between 45 and 55%. Minimal absolute values during SLV correlated with non-respiratory SOFA (R2=0.090, p=0.0287) as well as the Clavien score (R2=0.098, p=0.0201), but did not correlate with any of the standard clinical monitoring parameters (SpO2, PaO2, PaCO2, Hb). By defining a threshold value of SctO2=65%, the Odds ratio of having a non-respiratory organ failure is 2.37 (95% CI=1.18 – 4.39, p=0.043) and a complication classified as a Clavien score higher that 0 is 3.19 (95% CI=1.60 – 6.34, p=0.0272).
Thoracic surgery necessitating a SLV is associated with a significant decrease of SctO2 and minimal SctO2 values seem to positively correlate with postoperative complications.
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Fyzioterapie na oddělení chronické resuscitační a intenzivní péče / Physiotherapy at the department of chronic resuscitation and intensive careSobotka, Daniel January 2007 (has links)
The principal aim of the thesis titled "Physiotherapy at Chronic Intensive Care Unit" (CICU) is to describe and analyze the not much known area of physiotherapy at the CICU and the various methods of its utilization. The thesis is structured in order to deal with the system at CICU, the typology of patients, physiotherapeutic methods and the ventilator modes. The patient should be taken care of by the multidisciplinary team which should cooperate in order to achieve a common goal - consecutive weaning followed by the liberating from the ventilator's support. The chapters about ergotherapy and psychological effects complete the overview of the topic. Practical part of the thesis consists of the survey file which represent the patient-family-doctor-physiotherapist point of view. Powered by TCPDF (www.tcpdf.org)
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Multiscale lung ventilation modeling in health and disease / Modélisation multi-échelle de la ventilation pulmonaire dans des cas sains et pathologiquesPozin, Nicolas 06 October 2017 (has links)
Les poumons sont constitués d’un arbre par lequel circule l’air et qui alimente le parenchyme où ont lieu les échanges gazeux avec le sang. Certaines pathologies affectent la structure de l’arbre ou du parenchyme induisant des défauts dans l’approvisionnement en air ou des efforts respiratoires accrus. Etudier l’organe in-vivo est complexe. La modélisation mathématique peut apporter un éclairage utile sur les effets associés aux pathologies touchant le poumon, et la pertinence des traitements proposés. Dans la première partie de cette thèse, nous proposons un modèle mécanique de ventilation pulmonaire. Un arbre 0D est couplé de manière forte à un modèle de parenchyme 3D. On met en évidence l’impact sur la distribution de ventilation des conditions aux limites et d’altérations de l’arbre ou du parenchyme. Le comportement de ce modèle est comparé à celui d’un modèle plus simple et couramment utilisé.Dans une deuxième partie, on propose un modèle d’arbre asthmatique et on étudie dans quelle mesure respirer un gaz moins dense que l’air permet de diminuer les efforts et les défauts de ventilation. On propose ensuite une approche visant à déterminer la distribution des constrictions bronchiques les plus sévères à partir de données d’imagerie. Notre démarche s’appuie sur l’utilisation du modèle de ventilation, enrichie par une technique d’apprentissage statistique.On présente finalement deux études prospectives. La première étend les modèles de ventilation introduits précédemment avec pour objectif de modéliser la spirométrie. La deuxième s’inscrit dans une perspective visant à déterminer la géométrie du poumon à partir de mesures simples prises sur le corps du patient. / The lungs contain a tree through which the air flows. It supplies a porous region, the parenchyma, where gas exchanges with blood take place. Some pathologies affect the tree structure or the parenchyma integrity. They can induce ventilation defects or increased respiratory efforts. In vivo-studies are complex and mathematical modeling can provide some insights on the lung behavior, the pathologies’ impacts or the efficiency of treatments.In the first part of this thesis, we propose a ventilation model of the lung based on a mechanical description. A 0D tree is strongly coupled to a 3D parenchyma model. We show the influence of chosen boundary conditions as well as tree or parenchyma alterations on the ventilation distribution. Results are compared with those provided by a simpler model, often used in the literature.In a second part, we use the tree-parenchyma coupled model to investigate how breathing gas mixtures less dense than air would potentially reduce efforts and ensure a better ventilation. To that end, we build an asthmatic tree model.In the next part, we develop an approach to get insights on severe constrictions distribution based on the analysis of dynamic lung ventilation images. To do so, the coupled ventilation model is used along with a machine learning technique.Finally, two prospective works are presented. First, we propose extensions to the ventilation models introduced in the first part as a step towards spriometry modeling. The last study is part of a global perspective that aims at getting insights on the lung geometry based on simple measurements on the patient’s body.
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Podpora ventilace u laboratorních zvířat / Ventilation Support of Laboratory AnimalsDaniš, Václav January 2016 (has links)
mechanical ventilation an inseparable part of almost all surgery, where is anesthesia used. The introductory chapters of this thesis are focus on a teoretical familiarization with the complex issue with artificial lung ventilation. In additional to the history of artificial lung ventilation, chapters included familiarization with anatomy and physiology of lungs, associated with this defined volume of lungs and itself pulmonary ventilation. In the practical part I deal with design of ventilator for used it on laboratory animals.
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Imagerie fonctionnelle de la ventilation et de l’inflammation pulmonaires lors d'agression pulmonaire aiguë expérimentale / Functional imaging of pulmonary ventilation and inflammation in an experimental model of lung injuryPouzot-Névoret, Céline 09 November 2010 (has links)
Le syndrome de détresse respiratoire aiguë (SDRA) est caractérisé par des lésions alvéolairesdiffuses qui résultent d’une lésion de la membrane alvéolo-capillaire entrainant entre autresune réaction inflammatoire intense et une perte massive et hétérogène du volume pulmonaireaéré. La tomographie par émission de positons (TEP) et la tomographie par impédanceélectrique (TIE) sont deux techniques d’imagerie fonctionnelle permettant l’étude noninvasive, quantitative et régionale du poumon.Ce travail présente le résultat d’études expérimentales conduites dans le SDRA. Tout d’abord,nous avons comparé positivement la TIE à la TEP pour la mesure de la ventilation pulmonaireet du volume aéré. Nous avons ensuite décrit et validé une technique robuste d’obtention duvolume aéré et de la ventilation spécifique en TEP sans prélèvement invasif. Enfin, nousavons étudié en TEP l’influence de la pression expiratoire positive (PEP) et du décubitusventral (DV) sur la répartition de la ventilation, de la perfusion et de l’inflammationpulmonaires. Les poumons agressés par l’acide chlorhydrique inhalé ont une inflammationsignificativement plus élevée que le groupe contrôle. Aucune différence significatived’inflammation n’a été trouvée entre les groupes expérimentaux malgré des modificationsimportantes de la répartition de la ventilation et de la perfusion régionales lors de la mise enDV. Ces études donc ont permis le développement d’un modèle porcin stable d’agressionpulmonaire aiguë et la validation de techniques d’imagerie permettant l’étude non invasive deparamètres physiologiques importants pouvant aider au réglage de la ventilation mécanique aucours du SDRA. / Acute respiratory distress syndrome (ARDS) is characterized by diffuse alveolar damage andresulting from an increased permeability of the alveolar-capillary membrane. Of notice, thereis an intense lung inflammation. Positron emission tomography (PET) and electricalimpedance tomography (EIT) allow noninvasive assessment of pulmonary ventilation,perfusion and inflammation. We use these techniques to decipher the impairments ofventilation and inflammation throughout the lungs in an experimental model of acute lunginjury by hydrochloric acid inhalation in pigs.In a first study, we compared EIT to PET in quantifying pulmonary aerated volume andventilation, using PET as a gold standard. We found that lung ventilation and volume wereaccurately measured with EIT over a wide range of lung volume and minute ventilation. Wehave then described and validated a new model to obtain lung aerated volume and ventilationwith PET, without the requirement of gas sampling in the respiratory circuit. Finally, weconducted a controlled study with PET to evaluate the effects of positive end-expiratorypressure and body position on regional lung inflammation, ventilation and perfusion.Inflammation was significantly higher in injured groups than in control. However, there wasno significant change in inflammation across ALI groups despite significant differencebetween ventilation and perfusion repartition.We have developed in this work a stable experimental model of acute lung injury andvalidated noninvasive imaging tools allowing studying of important physiologic parametersthat could help setting up mechanical ventilation.
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Ošetřovatelské postupy u komplikované peritonitis / Nursing procedures at complicated peritonitisPokorná, Lenka January 2019 (has links)
(v AJ) For my diploma thesis I chose Nursing care for patients with complicated peritonitis as a topic, because care for these patients must be complex and often requires long-term stay at the anesthesiology and resuscitation department. These patients require organ support, undergo repeated surgical revisions, and ultimately, if they overcome this critical period, they learn very often self- care, walking, and sometimes adapt to permanent changes in health. It is a disease where there are often sudden changes in the patient's condition. In the theoretical part I tried to describe the disease leading to the development of peritonitis and complications in the form of septic shock and multiorgan failure. In the National Medical Library, I have searched for a comprehensive review of literature since 2005. I searched for keywords and phrases: Peritonitis, Nursing Care, Sepsis, Multiorgan Failure, Circulatory Support, Artificial Pulmonary Ventilation, Continuous Function Replacement kidney care, laparotomy care, drainage care, intra-abdominal hypertension. I obtained other documents using the central search engine UKAŽ, I drew from licensed databases: Bibliographia medica Čechoslovaca, Ebsco, Medline, Pubmed. For the processing of nursing procedures I used the recommendations of professional societies:...
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Pathophysiological and Histomorphological Effects of One-Lung Ventilation in the Porcine LungKozian, Alf January 2009 (has links)
Thoracic surgical procedures require partial or complete airway separation and the opportunity to exclude one lung from ventilation (one-lung ventilation, OLV). OLV is commonly associated with profound pathophysiological changes that may affect the postoperative outcome. It is injurious in terms of increased mechanical stress including alveolar cell stretch and overdistension, shear forces secondary to repeated tidal collapse and reopening of alveolar units and compression of alveolar vessels. Ventilation and perfusion distribution may thus be affected during and after OLV. The present studies investigated the influence of OLV on ventilation and perfusion distribution, on the gas/tissue distribution and on the lung histomorphology in a pig model of thoracic surgery. Anaesthetised and mechanically ventilated piglets were examined. The ventilation and perfusion distribution within the lungs was assessed by single photon emission computed tomography. Computed tomography was used to establish the effects of OLV on dependent lung gas/tissue distribution. The pulmonary histopathology of pigs undergoing OLV and thoracic surgery was compared with that of two-lung ventilation (TLV) and spontaneous breathing. OLV induced hyperperfusion and significant V/Q mismatch in the ventilated lung persistent in the postoperative course. It increased cyclic tidal recruitment that was associated with a persistent increase of gas content in the ventilated lung. OLV and thoracic surgery as well resulted in alveolar damage. In the present model of OLV and thoracic surgery, alveolar recruitment manoeuvre (ARM) and protective ventilation approach using low tidal volume preserved the ventilated lung density distribution and did not aggravate cyclic recruitment of alveoli in the ventilated lung. In conclusion, the present model established significant alveolar damage in response to OLV and thoracic surgery. Lung injury could be related to the profound pathophysiological consequences of OLV including hyperperfusion, ventilation/perfusion mismatch and increased tidal recruitment of lung tissue in the dependent, ventilated lung. These mechanisms may contribute to the increased susceptibility for respiratory complications in patients undergoing thoracic surgery. A protective approach including sufficient ARM, application of PEEP, and the use of lower tidal volumes may prevent the ventilated lung from deleterious consequences of OLV.
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