Dissertationen zum Thema „Lung“
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Eriksson, Leif. „Lung transplantation clinical and experimental studies /“. Lund : Depts. of Cardiothoracic Surgery, Respiratory Medicine and Clinical Physiology, University of Lund, 1998. http://catalog.hathitrust.org/api/volumes/oclc/39068785.html.
Der volle Inhalt der QuelleJohansson, Soller Maria. „Cytogenetic studies of lung tumors“. Lund : Dept. of Clinical Genetics, University of Lund, 1994. http://catalog.hathitrust.org/api/volumes/oclc/39068855.html.
Der volle Inhalt der QuelleWilson, Wendy Lee. „Xanthine oxidase in the lung“. Thesis, University of British Columbia, 1987. http://hdl.handle.net/2429/26669.
Der volle Inhalt der QuelleMedicine, Faculty of
Pathology and Laboratory Medicine, Department of
Graduate
Bastin, Anthony John. „Modulation of lung injury after lung resection“. Thesis, Imperial College London, 2011. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.536026.
Der volle Inhalt der QuelleWolf, Samuel J., Alexander P. Reske, Sören Hammermüller, Eduardo L. V. Costa, Peter M. Spieth, Pierre Hepp, Alysson R. Carvalho et al. „Correlation of lung collapse and gas exchange“. Universitätsbibliothek Leipzig, 2015. http://nbn-resolving.de/urn:nbn:de:bsz:15-qucosa-176099.
Der volle Inhalt der QuelleJohnsson, Hans. „Lung hyaluronan and lung water in the perinatal period“. Doctoral thesis, Uppsala : Acta Universitatis Upsaliensis : Univ.-bibl. [distributör], 2001. http://publications.uu.se/theses/91-554-4989-1/.
Der volle Inhalt der QuelleCherukupalli, Kamala. „Studies on the normal and abnormal lung growth in the human and in the rat with emphasis on the connective tissue fibers of the lung“. Thesis, University of British Columbia, 1989. http://hdl.handle.net/2429/30607.
Der volle Inhalt der QuelleMedicine, Faculty of
Pathology and Laboratory Medicine, Department of
Graduate
Trávníčková, Hana. „Implementace přenosového protokolu pro přenos dat mobilní cirkulační jednotky pro převoz plic“. Master's thesis, Vysoké učení technické v Brně. Fakulta elektrotechniky a komunikačních technologií, 2014. http://www.nusl.cz/ntk/nusl-220838.
Der volle Inhalt der QuelleIrving, Samantha. „Gas mixing in the lungs of children with obstructive lung disease“. Thesis, Imperial College London, 2014. http://hdl.handle.net/10044/1/25402.
Der volle Inhalt der QuelleGrewal, Amardeep Singh. „Prevalence and Outcome of Lung Cancer in Lung Transplant Recipients“. Thesis, Harvard University, 2015. http://nrs.harvard.edu/urn-3:HUL.InstRepos:17295910.
Der volle Inhalt der QuellePrime, David. „The hydraulic lung“. Thesis, Cranfield University, 2004. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.420674.
Der volle Inhalt der QuelleAdams, Angelique Fiona Pelicano. „The Smoking Lung“. Thesis, The University of Arizona, 2015. http://hdl.handle.net/10150/579414.
Der volle Inhalt der QuelleGlendinning, Laura. „Sheep lung microbiota“. Thesis, University of Edinburgh, 2017. http://hdl.handle.net/1842/29541.
Der volle Inhalt der QuelleKamenz, Carsten. „Book-lung morphology“. Doctoral thesis, Humboldt-Universität zu Berlin, Mathematisch-Naturwissenschaftliche Fakultät I, 2010. http://dx.doi.org/10.18452/16070.
Der volle Inhalt der QuelleStrict comparative analyses of the morphology of arachnid book lungs (Arachnida Lamarck, 1801 - Arthropoda: Chelicerata) were carried out in the present doctoral thesis using modern methods, resulting in a new perspective on arachnid phylogeny. Comparisons with potential aquatic sistergroups (Xiphosura and/or Eurypterida) and fossil scorpions give rise to the hypothesis of the unique terrestrialization of ancestors, which is common for all arachnids. Data from 200 Recent + 2 extinct scorpions, 16 whip spiders (Amblypygi), 17 whip scorpions (Thely-phonida), 1 schizomid (Schizomida), 1 extinct trigonotarbid (Trigonotarbida) and 1 outgroup - horseshoe crab (Xiphosura) are assembled into an illustrated catalogue of arachnid book lungs. Following the observations of these gradually differing cuticular structures the vast variation of book-lung fine structure across Arachnida requires unequivocal definition of characters and character states. Five characters are defined, which are assigned to distinct homologous book-lung structures: (1) the surface structure of the respiratory lamellae, (2) structure of the distal edges of the lamellae, (3) the posterior edge of the spiracle, (4) the anterior edge of the spiracle and (5) the structure of the wall lining the atrial chamber. Especially the book-lung characters 1-3 contain unexpected information, which helps resolve relationships within Scorpiones to a high degree, and characters 4 and 5 are of considerable importance for Uropygi s. lat. One sixth character (sensilla/pores) is mentioned, but sporadically examined. However, cuticular book-lung fine structure is studied using SEM, the gross morphology is reassessed using histological sectioning and 3D-reconstructions based on µCT. For investigations on trigonotabid fossils a new method yielding 3D-reconstructions from stacks of subsequent focal layers was developed.
Lehtonen, S. (Siri). „Localization and regulation of peroxiredoxins in human lung and lung diseases“. Doctoral thesis, University of Oulu, 2005. http://urn.fi/urn:isbn:9514277651.
Der volle Inhalt der QuelleLee, Richard. „An improved system for lung cancer diagnosis using lung cell images“. Diss., Online access via UMI:, 2006.
Den vollen Inhalt der Quelle findenMin, Yugang. „4D-CT Lung Registration and its Application for Lung Radiation Therapy“. Doctoral diss., University of Central Florida, 2012. http://digital.library.ucf.edu/cdm/ref/collection/ETD/id/5340.
Der volle Inhalt der QuelleID: 031001565; System requirements: World Wide Web browser and PDF reader.; Mode of access: World Wide Web.; Advisers: Sumanta N. Pattanaik, Anand P. Santhanam.; Title from PDF title page (viewed August 26, 2013).; Thesis (Ph.D.)--University of Central Florida, 2012.; Includes bibliographical references (p. 77-83).
Ph.D.
Doctorate
Computer Science
Engineering and Computer Science
Computer Science
Heeley, Emma Louise. „Lung surfactant and secretory phospholipase Aâ†2 in inflammatory lung disorders“. Thesis, University of Southampton, 2000. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.323970.
Der volle Inhalt der QuelleRäsänen, Noora. „Venous Thromboembolism after Thoracotomy and Lung LobectomyIn Patients with Lung Malignancy“. Thesis, Örebro universitet, Institutionen för medicinska vetenskaper, 2019. http://urn.kb.se/resolve?urn=urn:nbn:se:oru:diva-73520.
Der volle Inhalt der QuellePan, Yue. „Currents- and varifolds-based registration of lung vessels and lung surfaces“. Thesis, University of Iowa, 2016. https://ir.uiowa.edu/etd/2257.
Der volle Inhalt der QuelleBingula, Rea. „Non-small cell lung cancer, immunity and microbiota : laying ground for the gut-lung-lung cancer axis in human subjects“. Thesis, Université Clermont Auvergne (2017-2020), 2019. http://www.theses.fr/2019CLFAS009.
Der volle Inhalt der QuelleLung cancer is the main cause of death by cancer worldwide. Despite the variety of available treatments, including surgery, chemotherapy, radiotherapy, and immune therapy, the average 5-year survival is 60%. One of the underlying reasons is a very high variability in patients’ susceptibility to treatment, explained by genetic background and since recently – our microbiota. The term microbiota includes bacteria, archaea, fungi, viruses and protists that inhabit our organism. The studies in animal models show that the gut microbiota (focused on bacteria) has a crucial role in host’s responsiveness to therapy through the stimulation of immune system. In this light, several “communication axes” between the gut and distal tumour sites have started to develop, including the “gut-lung” axis. However, the resident microbiota in the lungs that could directly influence the tumour response and interact with the gut microbiota has been scarcely characterised. To enable further development of the idea of the “gut-lung-lung cancer” axis, we included 18 non-small cell lung cancer (NSCLC) patients eligible for surgery and analysed the microbiota from four different lung samples (non-malignant, peritumoural and tumour tissue and bronchoalveolar lavage fluid; BAL), saliva and faeces by high-throughput sequencing. We also analysed several immune markers, as lymphocytic tumour infiltrate, Th and neutrophil profiles and cytokines in BAL and blood, and inflammatory markers in faeces along with short-chain fatty acids. Focusing first on the lungs, we show that BAL microbiota represents a significantly distinct community compared to lung tissue microbiota by providing detailed characterisation of the four different lung samples. Since tumours in lower lobes are reported as the ones with the worse prognosis, we investigated how the lobe location affected the microbiota composition. Peritumoural tissue and BAL microbiota were identified as the most affected in both abundance and diversity, and tumour as the least affected. However, phylum Firmicutes, previously reported as elevated in chronic obstructive pulmonary disease compared to controls, was found more abundant in microbiota from lower lung lobes. Therefore, we propose that both increase in Firmicutes and extensive changes in peritumoural tissue could be associated to increased aggressiveness of the lower lobe tumours. Next, we show that the presence of metastatic lymph nodes (LN), negative prognostic marker in NSCLC, significantly influence the local tissue microbiota in relation to its respiratory profile. We reported that anaerobic bacteria were more abundant within the tumour in the presence of metastatic LN, and aerobic bacteria within the one without it. Moreover, exactly inverse was observed for the same bacteria in extratumoural tissues. Along with migratory hypothesis depending on the bacterial preference for growth conditions shaped by tumour’s features, we propose several biomarkers for detection of metastatic LN that might facilitate their detection without imposing LN biopsy. Finally, we showed that BAL microbiota is the most associated to the local immune response and independent of the presence of metastatic LN. Future research will focus on the exploration of the interaction between the lung microbiota, systemic immunity and the gut microbiota
Fisher, Andrew John. „The effect of donor lung injury on outcome after human lung transplantation“. Thesis, University of Newcastle Upon Tyne, 2001. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.391976.
Der volle Inhalt der QuelleNelson, Kevin Joseph. „MICRORNA REGULATION OF VENTILATOR INDUCED LUNG INJURY AND PRESSURE-INDUCED LUNG INFLAMMATION“. The Ohio State University, 2016. http://rave.ohiolink.edu/etdc/view?acc_num=osu1462276463.
Der volle Inhalt der QuelleDe, Souza Nicosha. „Molecular epidemiology of lung cancer in the Liverpool Lung Project (LLP) cohort“. Thesis, University of Liverpool, 2014. http://livrepository.liverpool.ac.uk/2006199/.
Der volle Inhalt der QuelleMotoyama, Hideki. „Plasmin administration during ex vivo lung perfusion ameliorates lung ischemia-reperfusion injury“. Kyoto University, 2015. http://hdl.handle.net/2433/200436.
Der volle Inhalt der QuelleKondo, Takeshi. „β2-Adrenoreceptor Agonist Inhalation During Ex Vivo Lung Perfusion Attenuates Lung Injury“. Kyoto University, 2016. http://hdl.handle.net/2433/215382.
Der volle Inhalt der QuelleKozian, Alf. „Pathophysiological and Histomorphological Effects of One-Lung Ventilation in the Porcine Lung“. Doctoral thesis, Uppsala universitet, Klinisk fysiologi, 2009. http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-108850.
Der volle Inhalt der QuelleMattes, Charlott, und Ulrich H. Thome. „Rapid elevation of sodium transport through insulin is mediated by AKT in alveolar cells“. Universitätsbibliothek Leipzig, 2014. http://nbn-resolving.de/urn:nbn:de:bsz:15-qucosa-142643.
Der volle Inhalt der QuelleGarrad, E. Philippa. „The effects of temperature change and lung expansion on lung liquid production in in vitro preparations of lungs from fetal guinea pigs (Cavia porcellus)“. Thesis, University of British Columbia, 1990. http://hdl.handle.net/2429/28989.
Der volle Inhalt der QuelleScience, Faculty of
Zoology, Department of
Graduate
Maksym, Geoffrey Nicholas. „Modelling lung tissue rheology“. Thesis, National Library of Canada = Bibliothèque nationale du Canada, 1997. http://www.collectionscanada.ca/obj/s4/f2/dsk2/ftp02/NQ30329.pdf.
Der volle Inhalt der QuelleMaksym, Geoffrey N. „Modelling lung tissue theology“. Thesis, McGill University, 1997. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=42087.
Der volle Inhalt der QuelleGaskin, Janet. „Radon and Lung Cancer“. Thesis, Université d'Ottawa / University of Ottawa, 2019. http://hdl.handle.net/10393/39003.
Der volle Inhalt der QuelleThomas, Akesh, zainab Fatima und Girendra resident Hoskere. „Lung Cancer in Tennessee“. Digital Commons @ East Tennessee State University, 2021. https://dc.etsu.edu/asrf/2021/presentations/69.
Der volle Inhalt der QuelleRuiz, Rossana, Marco Galvez-Nino, Ebert Poquioma, Abel Limache-García, Edgar Amorin, Mivael Olivera, Natalia Valdiviezo et al. „Lung Cancer in Peru“. Elsevier Inc, 2020. http://hdl.handle.net/10757/652438.
Der volle Inhalt der QuelleRevisión por pares
Katre, Ashwini A. „Ozone and lung fibrosis“. Thesis, Birmingham, Ala. : University of Alabama at Birmingham, 2009. https://www.mhsl.uab.edu/dt/2009m/katre.pdf.
Der volle Inhalt der QuelleLevin, Andrew Ian. „A study of right ventricular function during one lung anesthesia“. Thesis, Stellenbosch : University of Stellenbosch, 2004. http://hdl.handle.net/10019.1/16060.
Der volle Inhalt der QuelleENGLISH ABSTRACT: Background to the study OLA can give rise to certain problems: 1. A significant decrease in lung volume is reported to occur in the dependent lung during OLA in the LDP. This decrease in lung volume can result in an acute increase in opposition to RV ejection. The potential problem is that the right ventricle is a thin walled structure that can generate considerably less work than the thicker walled LV. It possesses little reserve to deal with an acute rise in afterload as may occur during acute lung injury or after lung resection. Therefore, this increase in afterload during OLA may potentially impair RV-PA coupling. Albeit this potential problem exists, the changes in RV afterload and how the right ventricle performs during OLA have not been well studied. 2. Arterial hypoxemia, due mainly to venous blood being shunted via the non-ventilated lung, may present a clinical problem during one lung ventilation. a. The relative resistances of the pulmonary vascular beds of the dependent ventilated and nondependent non-ventilated lungs are an important factor governing shunting and thus arterial oxygenation during one lung anesthesia. A high non-ventilated lung PVR and low ventilated lung PVR will facilitate good arterial oxygenation during OLA. An increase in non-ventilated lung PVR is governed predominantly by hypoxic pulmonary vasoconstriction. A low opposition to pulmonary blood flow in the dependent lung is facilitated predominantly by a high alveolar oxygen tension and normal lung volume, albeit other factors also play a role in this regard. b. The saturation and oxygen content of mixed venous blood will contribute significantly to the arterial oxygenation in the presence of a large shunt as occurs during OLA. i. On the one hand, venous desaturation as a cause of hypoxemia during one lung anesthesia has not as yet been systematically addressed in the literature. ii. On the other hand, if RV afterload increases to such a degree that it leads poor RV performance, this may cause impairment of global circulatory efficiency and lead to mixed venous desaturation. The question that has been raised is whether inotrope infusions could improve RV and LV performance, cardiac output, and thereby the efficiency of the circulation. Increases in the efficiency of the circulation will result in an improvement in mixed venous and arterial oxygenation in the presence of a large shunt. Nonetheless, the administration of inotrope infusions in the presence of a shunt and during OLA has been reported to aggravate hypoxemia. Thus at the time of conducting the study, conflicting reports of whether increasing cardiac output and thereby mixed venous oxygenation would increase or decrease arterial oxygenation during OLA In the light of the above, the researcher thus investigated RV afterload, RV performance and coupling to its load during OLA. The study also addressed the question whether different levels of inotrope infusion or PEEP hadbeneficial or deleterious effects on RV afterload, RV performance and coupling to its load during OLA. Furthermore, if cardiac output increased during OLA secondary to the infusion of inotropes, would this improve the efficiency of the circulation, mixed venous oxygenation and thus the arterial oxygenation during OLA, or would it worsen shunt and arterial oxygenation during OLA? Control group: OLA and the opposition to pulmonary flow Pulmonary arterial elastance increased by between 18 to 36% during OLA and mean PAP rose by 32% after initiation of OLA This increase in mean PAP on initiation of OLA is greater than that observed by certain investigators but similar to that seen previously in patients with damaged lungs. The question arose as to why pulmonary artery pressure rises during OLA? From consideration of Ohm’s law, pressure may be regarded as the product of flow and resistance (Mark, Slaughter et al. 2000). The increase in mean PAP during OLA is due to two reasons. 1. Firstly, the pressure versus flow curve is likely to be steeper during OLA. This is because pulmonary vascular recruitment and dilatation (pulmonary vascular reserve) is more limited in scope in these patients than is usual and most likely accounts for the increase in pulmonary artery pressure during OLA. The reasons for the limited pulmonary vascular reserve in the DL during OLA include: a. The pulmonary vascular bed of patients subjected to OLA is frequently abnormal because of its underlying pathology, b. During OLA in the lateral decubitus position, lung volume decreases to a greater degree than during two-lung anesthesia (Klingstedt, Hedenstierna et al. 1990). c. This decrease in lung volume will be further aggravated by DLT malpositions, secretions and blood, and absorption atelectasis due to the use of high concentrations of oxygen (Hedenstierna 1998; Krucylak, Naunheim et al. 1996). d. Excessive amounts of extrinsic or intrinsic PEEP during OLA can compress the intra-alveolar capillaries and deleteriously affect the pulmonary vascular resistance (Ducros, Moutafis et al. 1999; Inomata, Nishikawa et al. 1997; Bardoczky, Yernault et al. 1996; Yokota, Toriumi et al. 1996). 2. Secondly, there is greater flow through this vascular bed that possesses a higher resistance. It is noteworthy that the increase in mean PAP did not exceed a value of 25 mm Hg during OLA, even though cardiac output increased by 30%. However, in studies conducted in patients with “damaged lungs”, greater increases in PA pressure (accompanied by a decrease in RVEF) have been reported to occur on PA ligation. A question arises as to why differences exist between PA clamping and OLA? The answer may well be that the observed plateau in the rise of PA pressure during OLA is as a result of progressive diversion of flow to the NDL as PA pressure rises. Support for such a suggestion comes from the observation that concomitant with increases in PA pressure during OLA, HPV is progressively inhibited and shunt fraction progressively rises. This increase in shunt fraction that has been observed to occur as PA pressure rises, reflects an increase in diversion of pulmonary blood flow to the NDL. The impact of diversion of this blood to the NDL is that it possibly acts as a safety mechanism limiting increases in PA pressure and other indices of opposition to pulmonary flow during OLA. This “blow-off effect” will protect the RV until PA clamping occurs.Control group: OLA and RV function The current study represented the opportunity to investigate the significance of the abovementioned increases in PA pressures and elastance on RV performance during OLA. The current study indicates that at the moderate (30%) increases in PAP that accompanied the initiation of OLA, RV performance, as judged by stroke volume, cardiac index, RVEF and RVSWI, did not deteriorate compared to the baseline awake status. In fact, cardiac output increased following surgical incision: this was probably due to sympathetic nervous system stimulation. This observation also fits in with other studies in which RV performance usually only begins to deteriorate when indices of opposition to RV ejection reach 200 to 250% of baseline. Furthermore, a constant preload, as indicated by unchanged central venous and pulmonary artery wedge pressures, and right ventricular end-diastolic volumes were observed throughout the study period. In other words, this increase in RV afyterlad did not cuse the RV to dilate durign OLA. The relationship between stroke work and afterload will vary, depending on the contractile reserve of the ventricle. In this regard, it could be concluded that under the conditions operative in the current study, the RV was operating on the upslope of the RVSWI versus Ea relationship. This supports the observation that RV function is well preserved during OLA. In conclusion, regarding the indices of opposition to pulmonary flow and RV performance during OLA, it can be concluded that: 1. Opposition to RV ejection increases. This is evidenced by a 30% rise in mean PAP and 18 to 36% increase in pulmonary arterial elastance. 2. Right ventricular performance as indicated by RVSWI, RVEF and stroke volume does not decrease during OLA compared with when the patients awake or subjected to two-lung anesthesia. 3. Furthermore, coupling between the RV and its load is well preserved during OLA. This would imply that the RV operates at close to maximal efficiency during OLA and that RV stroke work reserve is present during OLA. It is likely that the RV, which continues operating as a flow pump as it does in normal life, easily copes with the small increases in RV afterload during OLA. Dobutamine during OLA: opposition to pulmonary flow and RV performance The effects of dobutamine infusions on RV performance during OLA can be summarised as follows: 1. Low rates of dobutamine infusion (3 ug.kg-1.min-1) increased cardiac output, stroke volume, and RVSWI. The administration of dobutamine 3 ug.kg-1.min-1 was not accompanied by increases in RV afterload. Therefore, low infusion rates of dobutamine did benefit RV-PA coupling during OLA. 2. However, administration of higher dosages of dobutamine (5 and 7 ug.kg-1.min-1) during OLA was associated with increases in certain indices of opposition to pulmonary blood flow. For example, PA elastance, mean PA pressure, and PVR increased by 30% to 40% compared to both when the patients were awake and when both lungs were being ventilated. Furthermore, PA compliance decreased by up to 61% when dobutamine 5 and 7 ug.kg-1.min-1 were infused compared to the OLA step when dobutaminewas not administered. The increases in mean PAP and PVR are considered to be of limited clinical significance. However, the decrease in PA compliance during the infusion of the highest dosage of dobutamine is clinically significant. PA compliance represents one of the factors determining vascular impedance in the Windkessel model of the circulation. The increases in opposition to pulmonary flow and lack of progressive increase in indices of RV performance are in contrast to what is expected to occur on administration of increasing dosages of the inotrope and pulmonary vasodilator, dobutamine. The reasons for the increase in opposition to pulmonary flow include exhaustion of the pulmonary vascular reserve during OLA at the high cardiac indices of 5 to 5.5 l.min-1.m-2. This aspect overshadowed the expected pulmonary vasodilator effects of dobutamine. Moreover, it is probable that the increase in RV afterload was significant enough to prevent right ventricular performance increasing as would be expected with the administration of progressively higher dosages of inotrope. While dobutamine was being administered during OLA, mean PAP increased to a maximum of 24.9 ± 6.2 mm Hg at a cardiac index of 5.5 ± 1.2 l.min-1.m-2. However during OLA, in the control group, mean PAP was 24.0 ± 7.7 mm Hg at the maximum cardiac index of 4.4 ± 1.1 l.min-1.m-2. This represented a relatively limited rise in PA pressure compared with administration of dobutamine alone. The most likely reason why there may have been a limited increase in mean PAP while dobutamine was being administered is that the “blow off” effect of the NDL vasculature limited the rise in PA pressure. Oxygenation during OLA With regard to oxygen flux, venous and arterial oxygenation during OLA in the control group, the following was observed: 1. Induction of anesthesia and the approximately 1O Celsius decrease in temperature induced an approximately 40% decrease in VO2 that continued during OLA. 2. Initiation of OLA resulted in an increase in cardiac output compared to baseline OLA and awake states. 3. The consequence was an increase in S��������O2 from 75% and P��������O2 from 5.4 kPa when the patients were awake to a P��������O2 of 9.0 ± 1.7 kPa and S��������O2 of 90.6 ± 4.7% during one-lung anesthesia. 4. During OLA, the significant increase in venous oxygenation resulted in an increase in arterial oxygenation compared to the awake state in spite of the approximately 37% shunt occuring during OLA. 5. Under conditions in the present study, dobutamine administration during OLA did not improve, but maintained the already high venous and arterial oxygenation compared with OLA alone. Therefore, the study hypothesis, that dobutamine would induce improvement in RVF and the increase in cardiac output during OLA would improve arterial oxygenation, does not hold in the current study. The hypothesis that dobutamine administration and improving cardiac output during OLA would increase arterial oxygenation was therefore rejected. However, the rejection of the hypothesis means that the findings of the current study are in contrast to the findings of Mathru et al, and Nomoto and Kawamura. These authors demonstrated that inotrope administration resulted in an increase in arterial oxygenation. Nonetheless, the different results are not at odds with each other. In fact, these differences help to clarify the effect of increases in cardiac output on arterial oxygenation in the presence of asignificant shunt. The differences between the studies can be explained in the following way. Conditions in the current study resulted in a favourable DO2/VO2 ratio and a high starting P��������O2 even before dobutamine administration was commenced. Therefore the venous saturations were on the flat part of the oxygen dissociation curve and also on the flat part of the relationship between cardiac output and arterial oxygen content originally described by Kelman, Nunn and colleagues. Further increases in cardiac output and the DO2/VO2 ratio would not be expected to, and did not, increase P��������O2, S��������O2, or C��������O2. Thus, arterial oxygenation content and saturation did not change subsequent to the increase in cardiac output associated with the administration of dobutamine in the current study. In contrast, in the Mathru study, the low starting venous saturations and tensions were improved by increases in the DO2/VO2 ratio. As the starting venous saturation was “low,” significant benefit in arterial oxygenation was obtained on increasing cardiac output in that study. One significant concern for the clinician regarding the administration of the inotrope dobutamine during OLA is that it may increase shunt fraction (Qs/Qt) and thereby decrease arterial oxygenation during one lung ventilation. The influence of dobutamine on arterial oxygenation during OLA may theoretically be related to the balance of the following divergent effects: 1. By improving the relationship between oxygen delivery and consumption, dobutamine increases P��������O2. This increase will benefit arterial oxygenation in the presence of a large shunt, 2. The above has to be weighed against possible increases in VO2 induced by dobutamine, the consequence of which will be a decrease in P��������O2. Such increases in VO2 were not seen on administration of dobutamine in the current study, 3. An increase in PA pressure accompanying the increased cardiac output will oppose HPV and increase shunt in both the dependent and non-dependent lungs, 4. Direct inhibition of HPV by dobutamine and, 5. The influence of P��������O2 on HPV (i.e. high levels of venous oxygenation will inhibit whereas low levels will potentiate HPV). Nonetheless, in spite of the concerns (risk) of hypoxemia on administering dobutamine during OLA, dobutamine administration did not decrease PaO2 or arterial oxygen saturation, and neither did it increase the cost of oxygenation compared to when OLA was conducted in the absence of dobutamine infusions. In addition, the findings of studies conducted by Mathru and colleagues, Nomoto and Kawamura and the current study indicate that under usual clinical conditions present during OLA in the LDP, the administration of low dosages of dobutamine do not increase shunt fraction. In fact, the beneficial effect of the increase in cardiac output on venous oxygenation resulted in an increase in arterial oxygenation in the study by Mathru and colleagues; similar mechanisms were most likely operative in the study conducted by Nomoto and Kawamura. Therefore, there is currently no evidence that the administration of dobutamine in dosages of up to 7 ug.kg-1.min-1 increases shunt and worsens arterial oxygenation in humans subjected to OLA in the LDP. It is apparent that the vasodilatory effects of dobutamine resulting in a possible increase in shunt fraction (Qs/Qt) is therefore not the only factor to consider when studying its effects on arterial oxygenation. What is also of great relevance whenconsidering the effects of an inotrope on arterial oxygenation is the effect of inotropic drugs on the venous oxygen content. It is possible that Qs/Qt could be increased by the administration of inotrope. Nonetheless, if venous oxygenation is favourably affected by the administration of dobutamine, then a depressant effect on arterial oxygenation by an increase in the amount of blood passing via the shunt may be negated. If the increase in venous oxygenation is very significant, there may even be benefits in terms of arterial oxygenation, as was the case in the current study. This approach to how the quality of the blood passing via the shunt affects arterial oxygenation shifts the emphasis on prevention and treatment of hypoxemia during OLA from the lung to the efficacy of the circulation. In other words, the emphasis is shifted from what predominantly happens to the non-ventilated lung (HPV) to primarily the efficacy of oxygen flux during OLA. Extrinsic and intrinsic PEEP and OLA The effects of PEEP on hemodynamics and oxygenation observed during OLA in the current study may be summarised as follows. When PEEP5 was applied to the DL during OLA in the current study: 1. Neither right ventricular function, hemodynamics, oxygen flux nor arterial oxygenation was affected by the application of PEEP5 compared to the step when no external PEEP was applied. 2. Significant amounts of intrinsic PEEP were present during OLA in the control group patients. The degree of intrinsic PEEP was weakly related to the degree of obstructive airways disease present on preoperative LFT’s. 3. The most likely reason why PEEP5 did not make a difference to oxygenation or hemodynamics was the existence of similar amounts of intrinsic PEEP during OLA. These findings confirm Myles’s contention that low levels of intrinsic PEEP may have salutary effects on oxygenation during OLA. When PEEP10 was applied to the DL during OLA in the current study, it led to a decrease in stroke volume. This decrease is predominantly due to a decrease in preload, as PVR does not increase to levels that are known to impair RV performance. The decrease in the DO2/VO2 ratio that was induced by PEEP10 predictably decreases P��������O2 and can potentially lead to impairment of arterial oxygenation. It can therefore be concluded that greater (excessive) amounts of PEEP under more unfavourable circulatory conditions than were observed in the current study, may have deleterious cardio-respiratory effects. In summary, optimising DL volume plays an important role in determining arterial oxygenation. However, the therapeutic index for PEEP is narrow and the anesthesiologist needs to know firstly when the lung volume of the DL approaches FRC and secondly, how to avoid dynamic hyperinflation of that lung. One significant problem is that the best method of monitoring FRC during OLA is not clear at present.
AFRIKAANSE OPSOMMING: Agtergrond tot die studie Eenlongnarkose mag tot sekere probleme aanleiding gee. ’n Betekenisvolle afname in volume van die onderlong vind in die laterale decubitus posisie tydens eenlongnarkose plaas. Hierdie afname in longvolume mag egter ’n akute verhoging in regter ventrikulêre nalading tot stand bring. Die probleem is egter dat die regter ventrikel ’n dunwandige struktuur is wat potensieel baie minder werk as die dikwandige linker ventrikel kan genereer. Die regter ventrikel het min reserwe om ’n akute verhoging in nalading te weerstaan soos wat gebeur met akute longbesering of na longreseksie. Dus die verhoging in nalading wat gepaard gaan met eenlongnarkose mag die koppeling tussen die regter ventrikel en die pulmonale arterie belemmer. Alhoewel hierdie potensiële probleem bestaan, is die verandering albei in regter ventrikulêre nalading en hoe die regter ventrikel funksioneer tydens eenlongnarkose nog nie goed bestudeer nie. 1. Arteriële hipoksemie, hoofsaaklik te wyte aan die groot aftakking via die long wat nie geventileer word nie, mag kliniese probleme tydens eenlongnarkose teweegbring. 2. Die weerstand wat die pulmonale vaskulêre beddens van die geventileerde en nie-geventileerde longe bied teen bloedvloei is belangrike faktore wat aftakking en dus arteriële oksigenasie tydens eenlongnarkose beheer. ’n Hoë weerstand van die nie-geventileerde long en ’n lae weerstand van die geventileerde long se pulmonale vaskulêre beddens sal bevredigende arteriële oksigenasie tydens eenlongnarkose fasiliteer. ’n Verhoging in die pulmonale vaskulêre weerstand van die nie-geventileerde long is hoofsaaklik te wyte aan hipoksiese pulmonale vasokonstriksie. ’n Lae pulmonale vaskulêre weerstand in die geventileerde onderlong is hoofsaaklik gefasiliteer deur ’n hoë alveolêre suurstofspanning en ’n normale long volume, alhoewel alle faktore ook ’n rol in hierdie verband speel. 3. In die teenwoordigheid van die groot aftakking wat bestaan tydens eenlongnarkose, sal die saturasie en suurstof inhoud van gemeng veneuse bloed ’n betekenisvolle bydrae aan arteriële oksigenasie maak. a. Veneuse saturasie as ’n oorsaak van hipoksemie tydens eenlongnarkose, is nog nie sistematies in die literatuur ondersoek nie. b. Indien regter ventrikulêre nalading tot so ’n mate verhoog dat dit tot swak ventrikulêre uitwerp lei, mag dit ’n oorsaak wees van ontoereikendheid van die globale bloedsomloop en tot gemeng veneuse desaturasie lei. Die vraag is dus of verhoging van die kardiale omset deur inotrope ondersteuning die toereikendheid van die sirkulasie kan verbeter. Verbeterde sirkulasie toereikendheid sal tot ’n verhoging in gemeng veneuse en arteriële oksigenasie lei in die teenwoordigheid van ’n groot aftakking. Nietemin, die toediening van inotrope in die teenwoordigheid van ’n groot aftakking tydens eenlongnarkose gerapporteer om hipoksemie te vererger tydens eenlongnarkose. Dus ten tye van die uitvoer van dié studie, is daar uitdrukking gegee tot teenstrydige opinies in die literatuur oftewel verhoging in kardiale omset arteriële oksigenasie sal verbeter of versleg tydens eenlongnarkose.In die lig van die agtergrond hierbo, het die navorser dus regter ventrikulêre nalading, regter ventrikulêre funksie en koppeling van die regter ventrikel met sy lading tydens eenlongnarkose ondersoek. Die studie het ook die vraag benader of inotroop infusies of PEEP goeie of slegte gevolge sou hê op regter ventrikulêre nalading, regter ventrikulêre funksie en koppeling van die regter ventrikel aan sy lading tydens eenlongnarkose. Sou die kardiale omset en die toereikendheid van die sirkulasie sou verbeter sekondêr tot die toediening van inotrope tydens eenlongnarkose, gemeng veneuse oksigenasie en dus arteriële oksigenasie tydens eenlongnarkose verbeter, of sou dit aftakking en arteriële oksigenasie versleg tydens eenlongnarkose? Kontrole groep Pulmonêre elastansie het tussen 18 en 36% verhoog en gemene pulmonale arterie druk het met 32% tydens eenlongnarkose vermeerder. Die verhoging in gemene pulmonale arterie druk met die aanvang van eenlongnarkose is groter as die waardes gesien deur sekere navorsers maar gelyk met waardes gevind in pasiënte met beskadigde longe. Die vraag ontstaan dan hoekom styg pulmonale arterie druk tydens eenlongnarkose? volgens Ohm se Wet, mag druk as die veelvoud van vloei en weerstand beskou word. Die verhoging in gemene pulmonale arterie druk tydens eenlongnarkose is daarvolgens hoofsaaklik te wyte aan twee redes. 1. Eerstens, die kurwe van druk teenoor vloei is waarskynlik styler tydens eenlongnarkose. Hierdie is omdat pulmonale vaskulêre werwing en verwyding (pulmonale vaskulêre reserwe) is meer beperk as nornaal in pasiënte met longsiekte. Hierdie is die waarskynlikste rede hoekom pulmonale arterie druk tydens eenlongnarkose verhoog. Die redes hoekom die pulmonale vaskulêre reserwe in die onderste long tydens eenlongnarkose beperk is sluit in die volgende: 1.1 Die pulmonale vaskulêre bed van pasiënte onderwerp aan eenlongnarkose mag abnormaal wees weens die onderliggende long patologie, 1.2 Tydens eenlongnarkose in die laterale decubitus posisie, is long volume in hoë mate verminder as tydens tweelongnarkose, 1.3 Die voorafgenoemde vermindering in longvolume sal verder verminder word deur wanposisies van die dubbellumenbuis, sekresies en bloed, en absorpsie atelektase. 1.4 Te hoë vlakke van PEEP, oftewel intrinsiek of ekstrensiek van oorsprong, sal die intraalveolêre vate toedruk en so die pulmonale vaskulêre weerstand verhoog. 2. Tweedens, is daar groter vloei deur hierdie vaskulêre bed wat ‘n hoër weerstand bevat. Dit is opmerkingswaardig dat die verhoging in gemene pulmonale arterie druk ‘n waarde van 25 mmHg nie oorskry het nie tydens eenlongnarkose, alhoewel kardiale omset met 30% verhoog het. In pasiënte met beskadigde longe, het vorige studies egter bewys dat groter verhoging in PA druk gebeur tydens afbinding van die pulmonale arterie. Die vraag ontstaan dus hoekom daar verskille bestaan tussen wat gebeur tydens afbind van die pulmonale arterie en eenlongnarkose? Die antwoord mag wees dat die beperking in die styging in PA druk tydens eenlongnarkose as gevolg van ‘n progressiewe afleiding van bloedvloei na die nie-geventileerde long gebeur sodra pulmonale arterie druk styg tydens eenlongnarkose. Die implikasie van die afleiding van bloed na die nie geventileerde long is dat dit as ‘n veiligheids meganisme optree en verdere styging in pulmonale arterie druk beperk tydens eenlongnarkose. Hierdie afblaas meganisme sal die regter ventrikel beskerm tot en met PA afbind.Kontrole groep: eenlongnarkose en regter ventrikulêre funksie Die huidige studie bied die geleentheid om die betekenis van die voorafgenoemde verhoging in PA drukke en elastansie op regter ventrikulêre funksie tydens eenlongnarkose te ondersoek. Die huidige studie dui aan dat die 30% verhoging in pulmonale arterie druk wat met die aanvang van eenlongnarkose plaasvind, glad nie regter ventrikulêre funksie belemmer nie indien dit vergelyk word met die basislyn wakker staat. In teendeel, kardiale omset het verhoog na chirurgiese insnyding: hierdie verhoging is waarskynlik te wyte aan simpatiese senuwee stimulasie na die chirurgiese insnyding. Hierdie waarnemings pas in ook met ander studies waartydens regter ventrikulêre ejeksie alleenlik begin om af te neem indien die indekse van opposisie tot regter ventrikulêre ejeksie 200 tot 250% van basislyn bereik. Verder, die induksie van voorlading, naamlik sentrale veneuse druk, pulmonale arterie wigdruk en regter ventrikulêre einddiastoliese volumes is onveranderd tydens die huidige studie; dit beteken die ventrikel het nie gedilateer het nie tydens die verhoging in regter ventrikulêre nalading. Die verband tussen slagwerk en nalading sal varieer, afhanklik van die kontraktiele status van die ventrikel. In hierdie opsig, kon ons aflei dat die regter ventrikel, onder omstandighede wat tydens diė studie plaasgevind het, gefunksioneer het op die stygende been van die verband tussen regter ventrikulêre slagwerk en pulmonale arterie elastansie. Hierdie waarneming ondersteun die argument in die vorige paragraaf dat die regter ventrikel funksie behoue is tydens eenlongnarkose. Ter opsomming omtrent die indekse van opposisie tot pulmonale vloei en regter ventrikulêre funksie tydens eenlongnarkose: 1. Opposisie tot regter ventrikulêre uitwerp verhoog. Die bewys hiervoor is ’n 30% verhoging in gemene pulmonale arterie druk en ’n 36% verhoging in pulmonale arterie elastansie. 2. Ten spyte van die verhoging in weerstand teen RV uitwerping, het regter ventrikulêre funksie (soos bepaal deur regter ventrikulêre slagwerk indeks, regter ventrikulêre ejeksie fraksie en slag volume), nie verminder tydens eenlongnarkose in vergelyking met die waardes verkry wanneer die pasiënte wakker is of aan tweelongnarkose onderwerp is. 3. Ons kon ook aflei dat die koppeling tussen die regter ventrikel en sy lading goed behoue is tydens eenlongnarkose. Die implikasie hiervan is dat regter ventrikulêre slagwerk reserwe teenwoordig is tydens eenlongnarkose. Tydens eenlongnarkose funksioneer die regter ventrikel as ’n vloeipomp, net soos in normale lewe; dit beteken dat en die klein verhoging in regter ventrikulêre nalading wat ondervind word tydens eenlongnarkose maklik getolereer word. Dobutamien tydens eenlongnarkose: opposisie tot pulmonale vloei en regter ventrikulêre funksie Die uitwerking van dobutamien op regter ventrikulêre funksie tydens eenlongnarkose kan as volg opgesom word: 1. Lae dosisse dobutamien (3 μg.kg-1.min-1) verhoog kardiale omset, slagvolume en regter ventrikulêre slagwerkindeks. Die toediening van dobutamien 3 μg.kg-1.min-1 het nie saamgegaan met ‘n verhoging in regter ventrikulêre nalading nie. Dus, lae dosisse van dobutamien het wel die koppeling tussen die regter ventrikel en die pulmonale vaskulatuur tydens eenlongnarkose verbeter.2. Nietemin, albei die hoër dosisse van dobutamien (5 en 7 μg.kg-1.min-1) tydens eenlongnarkose het verhogings in die opposisie tot pulmonale bloedvloei teweeggebring. Byvoorbeeld, PA elastansie, gemene PA druk en pulmonale vaskulêre weerstand het met 30 tot 40% verhoog in vergelyking met die waardes gekry toe die pasiënte wakker was en toe albei longe geventileer is. ’n Belangrike opmerking in hierdie opsig is dat pulmonale arterie vervormbaarheid tydens eenlongnarkose met 61% verminder het tydens albei dobutamien 5 en 7 μg.kg-1.min-1. Die verhogings in gemene pulmonale arterie druk en pulmonale vaskulêre weerstand is, volgens mening, nie van kliniese of statistiese betekenis nie, alhoewel die vermindering in PA vervormbaarheid tydens die dobutamien 7 μg.kg-1.min-1 infusie wel van kliniese betekenis is. PA vervormbaarheid weerspieël een van die faktore wat vaskulêre impedansie in die 3- element Windkessel model van sirkulasie het. Die verhoging in opposisie tot pulmonale vloei en die afwesigheid van progressiewe verhogings in indekse van regter ventrikulêre funksie is nie wat verwag word indien die dosisse van die inotroop en pulmonale vasodilator dobutamien, progressief verhoog word. Die redes hoekom die opposisie tot pulmonale vloei verhoog tydens die toediening van dobutamien sluit in die uitwissing van die pulmonale vaskulêre reserwe tydens eenlongnarkose. Tydens die hoë kardiale indekse van 5 tot 5.5 μg.kg-1.min-1. is die pulmonale vaskulêre reserwe uitgeput en die meganisme het die verwagte pulmonale vaskulêre vasodilatasie van dobutamien oorskadu. Bowendien is dit waarskynlik dat die verhoging in regter ventrikulêre nalading betekenisvol genoeg was om te verhoed dat regter ventrikulêre funksie progressief verhoog soos sou verwag word met die administrasie van hoër dosisse inotroop. Die administrasie van dobutamien tydens eenlongnarkose het gemene pulmonale arterie druk verhoog tot ’n maksimum van 24,9 ± 6.2 mm Hg teen ’n kardiale indeks van 5.5 ± 1.2 l.min-1.m2. Nietemin is gemene pulmonale arterie druk 24.0 ± 7.7 mm Hg teen die maksimum kardiale indeks in die kontrole groep van 4.4 ± 1.1 l.min-1.m-2 tydens eenlongnarkose in die kontrole groep. Hierdie weerspieël dus ’n relatief beperkte verhoging in pulmonale arterie druk in vergelyking met die verhoging in pulmonale arterie druk wat gebeur het tydens die administrasie van dobutamien. Die waarskynlikste rede hoekom daar ’n beperkte verhoging in pulmonale arterie druk sou gewees het tydens die infusie van dobutamien is die afblaas effek van die nie-geventileerde long wat die verhoging in PA druk beperk het. Oksigenasie tydens eenlongnarkose Die volgende waarnemings is gemaak in verband met suurstof vloed, veneuse en arteriële oksigenasie tydens eenlongnarkose in die kontrole groep: 1. Die kombinasie van Induksie van narkose en die 1ºC vermindering in temperatuur het saamgegaan met ’n 40% vermindering in suurstof verbruik tydens twee long narkose. Hierdie vermindering in suurstof verbruik het voortgegaan tydens eenlongnarkose. 2. Die aanvang van eenlongnarkose is geassosieerd met ’n verhoging in kardiale omset in vergelyking met albei die basislyn eenlongnarkose en wakker state. 3. Die gevolge van punte 1 en 2 hierbo is dat die gemengde veneuse suurstof saturasie vanaf 75% en die gemeng veneuse suurstof spanning vanaf 5.4 kPa (toe die pasiënte wakker was) gestyg het tydens4. Tydens eenlongnarkose het die betekenisvolle verhoging in veneuse oksigenasie veroorsaak dat daar ’n verhoging in arteriële oksigenasie was in vergelyking met wanneer die pasiënte wakker was. Hierdie styging in arteriele oksigenasie was ten spyte van die 37% aftakking wat teenwoordig was tydens eenlongnarkose. 5. Onder toestande in die huidige studie, het dobutamien tydens eenlongnarkose nog arteriële nog veneuse oksigenasie verbeter nie, maar die arteriele oksigenasie het konstant gebly. ’n Belangrike observasie wat daarmee saamgaan is dat dobutamien toediening nie met ’n daling in arteriële suurstof spanning geassosieer is nie. Vervolgens, die hipotese dat die verhoging in kardiale omset geassosieer met dobutamien toediening tydens eenlongnarkose ’n verhoging in arteriële oksigenasie beweeg bring, is dus verwerp. Die verwerping van die hipotese van die deel van die studie beteken dat die bevindinge die teenoorgestelde is van die studies gepubliseer deur Mathru en sy kollegas en Nomoto en Kawamura. Hierdie outeurs het gedemonstreer dat die toediening van inotrope ’n verhoging in arteriële oksigenasie teweeg gebring het. Nietemin is die teenoorgestelde gevolgtrekkinge nie teenstrydig met mekaar nie. Inteendeel hierdie verskille help ons om die effek van ’n verhoging in kardiale omset of arteriële oksigenasie in die teenwoordigheid van ’n betekenisvolle aftakking duidelik te maak. Die verskille tussen die studies kan op die volgende manier verduidelik word. Toestande wat in die huidige studie teenwoordig was het veroorsaak dat die verband tussen suurstof lewering en verbruik baie hoog was en dat die gemeng veneuse suurstof spanning baie hoog was om mee te begin alvorens dobutamien geinfuseer is. Dus is die veneuse saturasies op die plat deel van albei die suurstof dissosiasie kurwe en ook van die verband tussen kardiale omset en arteriële suurstof inhoud oorspronklik deur Kelman, Nunn en kollegas beskryf. Verdere verhogings in kardiale omset sou dus nie verwag word, en het nie, verhogings in gemeng veneuse suurstof spanning, gemeng veneuse suurstof saturasie of gemeng veneuse suurstof inhoud teweeg gebring. Dus, arteriële suurstof inhoud en saturasie het nie verander na die verhoging in kardiale omset wat teweeg gebring is deur die toediening van dobutamien in die huidige studie. Inteendeel, in die studie deur Mathru en kollegas, is die lae aanvanklike veneuse saturasie en spanning verbeter deur verhogings in die verband tussen suurstoflewering en suurstofverbruik. Omdat die veneuse saturasie aan die begin van die Mathru studie laag was, is betekenisvolle voordeel in arterieël oksigenasie teweeg gebring deur om die kardiale omset te verhoog. ’n Groot bekommernis vir die klinikus is dat die aftakking mag verhoog met die toediening van die inotroop dobutamien tydens eenlongnarkose en, op die manier, arteriële oksigenasie mag verminder. Die invloed van dobutamien op arteriële oksigenasie tydens eenlongnarkose mag teoreties te wyte wees aan die balans van die volgende uiteenlopende faktore: 1. Deur om die verband tussen suurstof lewering en verbruik te verbeter, sal dobutamien gemeng veneuse suurstof spanning verhoog. Hierdie verhoging sal arteriële oksigenasie verbeter in die teenwoordigheid van ’n groot aftakking, 2. Die bogenoemde moet teenoor potensiële verhogings in suurstofverbruik deur dobutamien oorweeg word. Die gevolge hiervan sou potensieel ’n vermindering in gemeng veneuse suurstof spanning wees. Sulke verhogings in suurstof verbruik is nie tydens die huidige studie gesien nie,3. ’n Verhoging in pulmonale arterie druk wat saamgaan met die verhoogde kardiale omset sal hipoksiese pulmonale vasokonstriksie teenwerk wat die aftakking in albei die geventileerde en nie geventileerde longe sal verhoog, 4. Direkte inhibisie van hipoksiese pulmonale vasokonstriksie deur dobutamien en, 5. Die invloed van gemeng veneuse suurstof spanning op hipoksiese pulmonale vasokonstriksie moet ook oorweeg word (d.i. hoe gemeng veneuse suurstof parsiele druk sal hipoksiese pulmonale vasokonstriksie inhibeer). Nietemin, ten spyte van die bekommernisse rondom hipoksemie tydens die toediening van dobutamien tydens eenlongnarkose, het dobutamien toediening nie ’n verlaging in arteriële suurstof spanning teweeg gebring nie, en ook het dit nie die koste van oksigenasie verhoog nie. Verder, die bevindinge van studies tydens eenlongnarkose in die laterale decubitus posisie deur Mathru en sy kollegas, Nomota en Kawamura en ook die huidige studie, dui aan dat die toediening van lae dosisse van dobutamien nie toe ’n verhoging in aftakking lei nie. Inteendeel, die voordelige effekte van die verhoging in kardiale omset op veneuse saturasie het veroorsaak dat daar ’n verhoging in arteriële saturasie is in die studie deur Mathru en sy kollegas soortgelyke meganismes is waarskynlik ook van toepassing in die studie wat gedoen is deur Nomoto en Kawamura. Dus, dwars deur die literatuur, is daar geen huidiglike bewys dat die toediening van dobutamien tot en met dosisse van 7μg.kg-1.min-1 aftakking verhoog of arteriële oksigenasie versleg in mense onderworpe aan eenlongnarkose in die laterale decubitus posisie. Dit is duidelik dat die vasodilatoriese effekte van dobutamien wat moontlik ’n verhoging in aftakking fraksie teweeg kan bring, nie die enigste faktore is om te oorweeg wanneer die middel se invloed op arteriële oksigenasie bestudeer word nie. Dit is ook van kliniese belang om die invloed van inotrope middels op veneuse suurstof inhoud te oorweeg. Dit is moontlik dat ’n aftakking verhoog kan word deur die toediening van ’n inotroop. Nietemin, mag die negatiewe effek wat die toediening van ’n inotroop sal inhou op arteriële oksigenasie deur middel van sy verhoging in aftakking, negeer word indien veneuse oksigenasie voordelig beïnvloed is. Verder, indien die verhoging in veneuse oksigenasie wat teweeggebring word deur die toediening van inotrope baie betekenisvol is, mag die gevolg hiervan wees dat arteriële oksigenasie voordelig beïnvloed word soos die geval in die huidige studie was. Die huidige benadering waar die kwaliteit van die bloed wat deur die aftakking vloei die arteriële oksigenasie beïnvloed, skuif die klem van voorkoming en behandeling van hipoksemie tydens eenlongnarkose van die long na die toereikendheid van die sirkulasie. Met ander woorde, die klem is geskuif van wat gebeur in die nie-geventileerde long (hipoksie pulmonale vasokonstriksie) tot primêr die toereikendheid van suurstof flux tydens eenlongnarkose. Ekstrinsieke en intrinsieke PEEP tydens eenlongnarkose Die invloed van PEEP op hemodinamika en oksigenasie tydens eenlongnarkose in die huidige studie mag as volg opgesom word. Toe PEEP5 tydens eenlongnarkose toegedien is: 1. Nie regter ventrikulêre funksie, hemodinamika, suurstof flux nog arteriële oksigenasie is beïnvloed deur die toediening van PEEP5 in vergelyking met die stap wanneer geen eksterne PEEP toegedien is nie. 2. Betekenisvolle hoeveelhede intrinsieke PEEP is teenwoordig tydens eenlongnarkose in die kontrole groep.Die hoeveelheid intrinsieke PEEP wat teenwoordig was, is swak maar betekenisvol verwant aan die graad obstruktiewe lugwegsiekte wat teenwoordig was gemeet deur pre-operatiewe longfunksie toetse. 3. Die waarskynlikste rede hoekom PEEP5 nie ’n verskil gemaak het aan oksigenasie of hemodinamika nie is die teenwoordigheid van soortgelyke hoeveelhede intrinsieke PEEP tydens eenlongnarkose. Hierdie bevinding bevestig Myle’s se beweringe dat lae vlakke intrinsieke PEEP voordelige effekte op oksigenasie tydens eenlongnarkose mag hê. PEEP10 toediening aan die onderlong tydens eenlongnarkose in die huidige studie het tot ’n vermindering in slagvolume gelei. Hierdie vermindering is primêr veroorsaak deur ’n vermindering in voorlading en nie die gevolg van ’n verhoging in pulmonale vaskulêre weerstand nie. Die gevolgtrekking is gemaak omdat regerventrikulere enddiastoliese volume verlaag het maar pulmonale vaskulêre weerstand het nie verhoog tot vlakke wat bekend is om regter ventrikulêre funksie te belemmer nie. Die vermindering in die verhouding tussen suurstof lewering en suurstof verbruik wat geïnduseer is deur PEEP10 het (voorspelbaar) gemeng veneuse suurstof spanning verminder en kon potensieël gelei het tot belemmering in arteriële oksigenasie. Indien minder voordelige sirkulatoriese toestande geheers het tydens die huidige studie, sou groter (oorbodige) hoeveelhede PEEP slegter kardiorespiratoriese gevolge tot gevolg gehad het. Ter opsomming, optimalisering van die volume van die onderlong tydens eenlongnarkose speel ’n belangrike rol in die bepaling van arteriële oksigenasie. Nietemin, die terapeutiese indeks vir PEEP is nou en die narkotiseur het die behoefte om te weet wanneer die volume van die onderlong optimaal is. In die opsig, is ’n betekenisvolle probleem tydens eenlongnarkose dat meting van funksionele residuele kapasiteit nie huidiglik maklik is nie
Brena, Romulo Martin. „Aberrant DNA methylation in human non-small cell lung cancer“. Columbus, Ohio : Ohio State University, 2007. http://rave.ohiolink.edu/etdc/view?acc%5Fnum=osu1172083621.
Der volle Inhalt der QuelleLakari, E. (Essi). „Expression of oxidant and antioxidant enzymes in human lung and interstitial lung diseases“. Doctoral thesis, University of Oulu, 2002. http://urn.fi/urn:isbn:9514266625.
Der volle Inhalt der QuelleLu, Yen-Ta. „Mechanisms of ischemia-reperfusion lung injury in the isolated, blood-perfused rat lung“. Thesis, Imperial College London, 1997. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.265706.
Der volle Inhalt der QuelleBirch, Jodie. „Telomere dysfunction and senescence in the ageing lung and age-related lung disease“. Thesis, University of Newcastle upon Tyne, 2015. http://hdl.handle.net/10443/3927.
Der volle Inhalt der QuelleSalvati, Valentina. „Development of effective lung cancer therapies based on lung cancer stem cella targeting“. Doctoral thesis, Università di Catania, 2015. http://hdl.handle.net/10761/4035.
Der volle Inhalt der QuelleTerlizzi, Michela. „Role of the inflammasome in lung cancer Inflammasome is involved in lung carcinogenesis“. Doctoral thesis, Universita degli studi di Salerno, 2017. http://hdl.handle.net/10556/2410.
Der volle Inhalt der QuelleLung cancer is recognized as one of the most devastating tumor worldwide due to the low rate survival over 5 years from the time of diagnosis. Inflammation has been widely recognized as the seventh hallmark of cancer as it facilitates the establishment/development and progression of lung cancer. In this context, recent evidence highlighted the role of the inflammasome during carcinogenesis. However, little is still known. The inflammasome is a multiprotein complex that leads to caspase-1 activation which role in lung cancer is still under investigated. In this context, the aim of my PhD project was to understand the role of the inflammasome in lung cancer in a mouse model of carcinogen-induced lung cancer and in human non-small cell lung cancer (NSCLC). We found that both caspase-1-dependent, the canonical pathway, and caspase-8/caspase-11-dependent, the non-canonical pathway, inflammasome were involved during lung cancer establishment and progression in both mice and humans. Our data showed that the pharmacological inhibition of both caspase-1 and caspase-8 significantly reduced lung tumor outgrowth associated to lower pro-inflammatory response and to a reduced lung recruitment of immunesuppressive cells and that caspase-8 was upstream caspase-1 activation during lung carcinogenesis. Furthermore, we showed that caspase-11 was the primary/main orchestrator of the inflammasome-dependent lung cancer progression and that the enzyme could be upstream of caspase-1 to induce the amplification of the occurring inflammatory process associated to lung cancer development. Finally, we identified a novel mechanism by which lung tumor-associated macrophages could favor lung tumorigenesis via the activation of caspase-11-dependent inflammasome and the consequent release of the pro-tumorigenic IL-1α. [edited by author]
XIV n.s.
Woods, Birgitta A. „The effects of epinephrine, AVP, norepinephrine, and acetylcholine on lung liquid production in in vitro preparations of lungs from fetal guinea pigs (Cavia porcellus)“. Thesis, University of British Columbia, 1991. http://hdl.handle.net/2429/29821.
Der volle Inhalt der QuelleScience, Faculty of
Zoology, Department of
Graduate
Chen, Patty P. 1981. „Lung tissue engineering : in vitro synthesis of lung tissue from neonatal and fetal rat lung cells cultured in a three-dimensional collagen matrix“. Thesis, Massachusetts Institute of Technology, 2004. http://hdl.handle.net/1721.1/28758.
Der volle Inhalt der QuelleIncludes bibliographical references (p. 76-77).
The focus of this study was to investigate the histology of tissue formed when fetal (16-20 days gestation) and neonatal (2 days old) rat lung cells were grown in a collagen-glycosaminoglycan scaffold. This project employed a collagen-GAG scaffold specifically developed for tissue engineering and investigated the effect of this substratum on the formation of lung histotypic structures in vitro. A cell isolation procedure was developed whereby 19-days gestation type II alveolar cells reaggregated to form alveolar-like structures. The effects of selected scaffold design variables including pore diameter and degradation rate of the substratum on lung tissue regeneration were explored. Lung cell behavior revealed as the cells interact with an analog of the extracellular matrix was also examined. Differences in fetal and neonatal lung cell behavior were identified using histological analysis. Lung cells were obtained from Sprague-Dawley rats after 16-, 19-, and 20-days of gestation and at 2 days after term. These cells were seeded into type I collagen-GAG matrices, sized 8mm in diameter by 2mm in thickness. The medium used, F12K and Ham's nutrient mixture, was supplemented with 10% fetal bovine serum. A seeding density between 1 to 5 million cells per sponge sample was used. Histology studies were performed at termination periods of 2, 14, and 28 days. This paper describes the in vitro formation and long-term maintenance of alveolar-like structures from enzymatically dissociated 19-days gestation fetal rat lung cells cultured on a collagen sponge substrate as a model system for lung tissue engineering.
by Patty P. Chen.
M.Eng.
Fuest, Sven [Verfasser]. „Protective signalling mechanisms in the lung induced by open-lung ventilation strategies / Sven Fuest“. Gießen : Universitätsbibliothek, 2014. http://d-nb.info/106847453X/34.
Der volle Inhalt der QuelleJackson, Erica L. (Erica Lynn) 1973. „Mouse models of lung cancer : understanding the molecular and cellular basis of lung tumorigenesis“. Thesis, Massachusetts Institute of Technology, 2003. http://hdl.handle.net/1721.1/29992.
Der volle Inhalt der QuelleIncludes bibliographical references.
Lung cancer is the leading cause of cancer deaths worldwide. Patients are typically diagnosed with advanced disease and have a high fatality:case ratio. Despite its prevalence, the identity of the cell of origin, precursor lesions and stages of disease progression have not been well characterized for most types of lung cancer. Furthermore, there are no effective screening methods for lung cancer and standard chemotherapeutics are ineffective in treating advanced lung cancer. The work presented here describes the development and characterization of a murine lung cancer model that uses conditional expression of oncogenic K-ras to drive tumorigenesis. The conditional allele is controlled by the Cre-loxP system. Using adenovirus to deliver Cre recombinase to the lungs we have controlled the timing and multiplicity of tumor initiation. We used this model to investigate several aspects of tumor biology. Timecourse experiments revealed the histologic stages of lung tumor progression, advancing from atypical adenomatous hyperplasia to adenoma to adenocarcinoma. Studies of early lesions provided insights into the ras effector pathways required for tumor initiation, implicating the JNK and p38 pathways in this process. In addition, our studies regarding the cell of origin of lung tumors led to the identification of a novel cell type in the adult lung that resembles an embryonic lung precursor cell.
(cont.) A common feature of mouse tumor models is that they mainly resemble the early stages of tumor development. In an effort to create a model representing advanced disease, we generated K-rasG12D;p53 compound mutant mice with varyious combinations of different conditional mutant p53 alleles. The compound mutant mice develop lung tumors that recapitulate several aspects of advanced human disease including stromal desmoplasia, invasion and metastasis. Missense mutation is the most common form of p53 mutation in human tumors, suggesting that the mutant p53 protein may confer a selective advantage on the tumor cells during tumorigenesis. Our comparison of the oncogenic effects of p53R172H, p53R270H and a conditional null allele, p53Fl, revealed that the p53R270H mutation results in a dominant negative allele. Furthermore, our studies revealed an oncogenic gain-of-function effect of both p53R172H and p53R270H on the development of nasopharyngeal carcinomas.
by Erica L. Jackson.
Ph.D.
Wakabayashi, Kenji. „Investigation of the mechanisms of acute lung injury, using an isolated perfused mouse lung“. Thesis, Imperial College London, 2012. http://hdl.handle.net/10044/1/10143.
Der volle Inhalt der QuelleŞeşen, Mustafa Berkan. „Lung cancer assistant : a hybrid clinical decision support application in lung cancer treatment selection“. Thesis, University of Oxford, 2013. https://ora.ox.ac.uk/objects/uuid:e0dd01e4-3f18-49ed-89af-5e81894d4967.
Der volle Inhalt der QuelleNishikawa, Shigeto. „Statins may have double-edged effects in patients with lung adenocarcinoma after lung resection“. Kyoto University, 2019. http://hdl.handle.net/2433/243305.
Der volle Inhalt der QuelleStabler, Collin Turner. „Optimizing Endothelial Repopulation of Decellularized Lung“. Diss., Temple University Libraries, 2016. http://cdm16002.contentdm.oclc.org/cdm/ref/collection/p245801coll10/id/388434.
Der volle Inhalt der QuellePh.D.
Decellularized lung tissue has been recognized as a potential platform to engineer whole lung organs suitable for transplantation or for modeling a variety of lung diseases. However many technical hurdles remain before this potential may be fully realized. Inability to efficiently re-endothelialize the pulmonary vasculature with a functional endothelium appears to be the primary cause of failure of recellularized lung scaffolds in early transplant studies. This dissertation research aims to enhance the re-endothelialization of decellularized rodent lung scaffolds with rat lung microvascular endothelial cells. This was achieved by adjusting the posture of the lung to a supine position during cell seeding through the pulmonary artery. The supine position allowed for significantly more homogeneous seeding and better cell retention in the apex regions of all lobes than the traditional upright position, especially in the right upper and left lobes. Additionally, the supine position allowed for greater cell retention within large diameter vessels (proximal – 100 µm to 5,000 µm) than the upright position, with little to no difference in the small diameter distal vessels. Endothelial cell adhesion in the proximal regions of the pulmonary vasculature in the decellularized lung was dependent on the binding of endothelial cell integrins, specifically α1β1, α2β1 and α5β1 integrins to, respectively, collagen type-I, type-IV and fibronectin in the residual ECM. Following in vitro maturation of the seeded constructs under perfusion culture, the seeded endothelial cells spread along the vascular wall, leading to a partial re-establishment of endothelial barrier function as inferred from a custom-designed leakage assay. The results of this dissertation research suggest that attention to cellular distribution within the whole organ is of paramount importance for restoring proper vascular function.
Temple University--Theses