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Allergen-induced change in airway responsiveness to direct and indirect stimuli in mild atopic asthmatics2014 September 1900 (has links)
Methacholine (MCh) and mannitol challenges are tests used to assess airway responsiveness. It has been shown that airway responsiveness to direct bronchoconstrictors like MCh tends to increase following exposure to allergen but the response to mannitol an indirect stimuli, is not known. Furthermore, the provocative concentration causing a 20% decrease in Forced Expiratory Volume in one second (FEV1) for adenosine 5’ monophosphate (AMP) correlates better to sputum eosinophilia than MCh PC 20. Hence, we hypothesized that airway responsiveness will be greater when measured with mannitol than MCh. We studied airway responsiveness to MCh and mannitol first at 3 hours and then later at 24 hours after allergen challenge. The 3-hour study yielded results contrary to our hypothesis therefore a twenty-four hour study was undertaken. Ten mild atopic asthmatics who had a positive MCh challenge and an allergic response to allergen extracts such as cat, horse, and house dust mite completed the 3-hour study. Eleven mild atopic asthmatics with the criteria above completed the 24-hour study. Both studies were non-blinded, randomized clinical trials. Airway responsiveness to MCh was quantitated by changes in PC20. Airway responsiveness to mannitol was quantitated as PD15 in the 3-hour study and dose response ratio (DRR) in the 24-hour study. In both studies, the allergen challenges were separated by 14 days. Fractional exhaled nitric oxide measurements (FENO) were collected in both studies at varying time points to track airway inflammation. In the 3-hour study, the geometric mean MCh PC20 decreased significantly after allergen exposure from 0.88 mg/ml to 0.50 mg/ml (p = 0.02) indicating airway responsiveness to MCh increased. Conversely, the geometric mean mannitol PD15 increased significantly from 174 mg to 284 mg (p =0.02) indicating a decrease in airway responsiveness to mannitol. In the 24-hour study, the geometric mean MCh PC20 again decreased significantly from 5.9 mg/ml to 2.2 mg/ml (p= 0.01) after allergen exposure. The mannitol DRR increased significantly from 63 mg/∆%FEV1 to 158 mg/∆%FEV1 (p = 0.03). FENO levels increased significantly in MCh arm but not mannitol arm. That is pre allergen challenge versus 24 hours after allergen challenge (for MCh arm: 26 ppb pre to 55 ppb post; for mannitol arm: 31 ppb pre to 39 ppb post). In conclusion, at three and twenty-four hours after allergen challenge, a time when the airways are more responsive to MCh, there is a significant decrease in airway responsiveness to mannitol.
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Optimizing and evaluation of a methacholine provocation test : with application in occupational researchSundblad, Britt-Marie January 2002 (has links)
<p>We have developed a methacholine provocation method, which detects bronchial responsiveness in more than 80% of healthy subjects. The method enables us to detect differences in bronchial responsiveness within the normal range. </p><p>With this method FEV1 and Gaw had similar sensitivity in detecting small differences in bronchial responsiveness. Differences, between protocols when using doubling or fourfold concentration steps emphasize the importance to strictly adhere to a predefined protocol. </p><p>Deep inhalation associated with the FEV1 manoeuvre decreases bronchial tone induced by methacholine for up to 6 minutes, which emphasizes the importance of exact timing between successive FEV1 measurements in bronchial provocation tests. There is a substantial overlap in bronchial responsiveness between healthy and asthmatic subjects and a deep inhalation at the end of the methacholine test challenge could not discriminate between asthmatic and non-asthmatic subjects.</p><p>Inhalation of dust in a swine confinement building causes an intense airway inflammatory reaction with an extensive migration of inflammatory cells, predominantly neutrophils, into the upper and lower airways. Bronchial responsiveness to methacholine increased by about 3 doubling concentration steps and was normalized one week after exposure. However, exposure to dust in a swine confinement building did not yield increased bronchial responsiveness to eucapnic hyperventilation with dry air which is often observed in asthmatic subjects. Exhaled NO was approximately doubled five hours after exposure and in the present study we found no relationship between exhaled NO levels and bronchial responsiveness in healthy subjects. </p><p>Protection with half-mask inhibited the dust induced increase of exhaled NO whereas the increase in bronchial responsiveness was influenced only to a minor extent.</p><p>These findings, do not support the hypothesis that the increased bronchial responsiveness following organic dust exposure is directly caused by the inflammation. Instead, a possible direct effect on the smooth muscle and swelling of the airway mucosa and increased secretions due to the general inflammatory reaction probably leads to airway narrowing enhancing the post-exposure bronchial response to methacholine. </p>
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Optimizing and evaluation of a methacholine provocation test : with application in occupational researchSundblad, Britt-Marie January 2002 (has links)
We have developed a methacholine provocation method, which detects bronchial responsiveness in more than 80% of healthy subjects. The method enables us to detect differences in bronchial responsiveness within the normal range. With this method FEV1 and Gaw had similar sensitivity in detecting small differences in bronchial responsiveness. Differences, between protocols when using doubling or fourfold concentration steps emphasize the importance to strictly adhere to a predefined protocol. Deep inhalation associated with the FEV1 manoeuvre decreases bronchial tone induced by methacholine for up to 6 minutes, which emphasizes the importance of exact timing between successive FEV1 measurements in bronchial provocation tests. There is a substantial overlap in bronchial responsiveness between healthy and asthmatic subjects and a deep inhalation at the end of the methacholine test challenge could not discriminate between asthmatic and non-asthmatic subjects. Inhalation of dust in a swine confinement building causes an intense airway inflammatory reaction with an extensive migration of inflammatory cells, predominantly neutrophils, into the upper and lower airways. Bronchial responsiveness to methacholine increased by about 3 doubling concentration steps and was normalized one week after exposure. However, exposure to dust in a swine confinement building did not yield increased bronchial responsiveness to eucapnic hyperventilation with dry air which is often observed in asthmatic subjects. Exhaled NO was approximately doubled five hours after exposure and in the present study we found no relationship between exhaled NO levels and bronchial responsiveness in healthy subjects. Protection with half-mask inhibited the dust induced increase of exhaled NO whereas the increase in bronchial responsiveness was influenced only to a minor extent. These findings, do not support the hypothesis that the increased bronchial responsiveness following organic dust exposure is directly caused by the inflammation. Instead, a possible direct effect on the smooth muscle and swelling of the airway mucosa and increased secretions due to the general inflammatory reaction probably leads to airway narrowing enhancing the post-exposure bronchial response to methacholine.
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Airway effects of diesel exhaust in healthy and asthmatic subjectsNordenhäll, Charlotta January 2002 (has links)
Several epidemiological studies have revealed an association between particulate matter (PM) pollution and various health effects. Importantly, there is evidence to suggest that individuals with pre-existing respiratory disease, such as asthma, are more sensitive to elevated ground levels of particulate matter as compared to healthy subjects. Among the various sources of PM pollution, diesel powered vehicles have been identified as important contributors. The aim of this thesis was to investigate the airway effects of experimental chamber exposure to diesel exhaust (DE) in healthy and asthmatic subjects, focusing on airway responsiveness, airway inflammation and lung function. To achieve a comprehensive picture of the airway responses to DE, a number of different methods were used, including lung function measurements, methacholine inhalation tests, induced sputum and bronchoscopy. Each subject acted as his/her own control by being exposed both to filtered air and DE in a crossover design. Short term exposure to DE, at a particle concentration (PMi0) of 300 ug/m3, was associated with a clinically significant increase in bronchial hyperresponsiveness in asthmatic subjects. In accordance with the epidemiological data suggesting a 1-4 day lag effect for most health outcomes to PM pollution, the increase was detected one day after DE exposure, indicating a long lasting response to DE in asthmatic airways. Diesel exhaust induced a range of airway inflammatory changes as reflected in induced sputum, bronchoalveolar lavage and bronchial mucosal biopsies. In healthy subjects, DE exposure was associated with an increase in neutrophils and IL-6 in sputum, elevated levels of IL-8 and IL-6 in bronchial wash (BW), enhanced expression of IL-8 and GRO-a in the bronchial epithelium and with increases in P-selectin and VCAM-1 in the airway mucosa. In contrast, asthmatics responded with an increase in IL-6 in sputum and an enhanced expression of IL-10 in the bronchial epithelium following exposure DE. Thus, clear differences were identified between healthy and asthmatic subjects in the inflammatory response to DE. Airway epithelial cells constitute the first line of cellular defence towards inhaled air pollutants and increasing evidence suggests that these cells contribute markedly to the initiation of airway inflammatory responses. The bronchial epithelium was identified to have an important regulatory role in response to diesel exhaust, including the capacity to produce chemoattractant and immunoregulatory proteins associated with development of airway inflammation and bronchial hyperresponsiveness. Lung function measurements revealed that short-term exposure to DE induces an immediate bronchoconstrictive response in both healthy and asthmatic individuals, with significant increases in airway resistance (Raw) following DE exposure. This thesis also investigated the effects of a lower concentration of DE (PMio 100 ug/m3) than previously studied. It was shown that exposure to DE at a concentration corresponding to a PM level that may be encountered in busy traffic situations, was still associated with potentially adverse airway responses in healthy and asthmatic subjects. In summary, the results presented here indicate that short term exposure to diesel exhaust, at high ambient concentrations, has the potential to induce a range of biological events in the airways of healthy and asthmatic subjects. / <p>Diss. (sammanfattning) Umeå : Umeå universitet, 2002, härtill 4 uppsatser.</p> / digitalisering@umu
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Role of N-methyl-D-aspartate receptors in the regulation of human airway smooth muscle function and airway responsivenessAnaparti, Vidyanand 15 June 2015 (has links)
Increased airway smooth muscle (ASM) mass contributes to airway hyperresponsiveness (AHR) in asthma and is orchestrated by growth factors, cytokines and chemokines. Airway contractile responses are influenced by neuromediators, such as acetylcholine, and glutamate released by parasympathetic and sympathetic airway nerves. Hyperactivity of these neural elements, termed neurogenic inflammation, is linked with hypercontractility and AHR. Glutamate is a non-essential amino acid derivative, and its physiological role is traditionally considered with respect to its being the primary excitatory neurotransmitter in brain, and regulation of neuronal development and memory. In allergic inflammation, immune cells including dendritic cells, neutrophils and eosinophils, constitutively synthesize and release glutamate, which signals through activation of glutamate receptors, most important among which are ionotrophic N-methyl D-aspartate receptors (NMDA-R). We hypothesized that glutamatergic signaling mediated through NMDA-Rs plays an important role in inducing functional Ca2+ responses in human (H) ASM cells that can underpin airway hypercontractility. We investigated the expression and function of NMDA-Rs in HASM cells, and assessed the effects of pro-inflammatory cytokines on NMDA-R expression and functional responses. Moreover, we measured airway responses to NMDA in mice, murine thin cut lung slice preparations, and floating collagen gels seeded with HASMs. Our data reveal that airway myocytes express multi-subunit NMDA-R complexes that function as receptor-operated calcium channels (ROCCs), mobilizing intracellular Ca2+ in ASM in vitro and airway contraction ex vivo. Individual airway myocytes treated with NMDA-R agonist exhibit disparate temporal patterns of intercellular Ca2+ flux that can be partitioned into four discrete function sub-groups. Further we show that tumor necrosis factor (TNF) exposure modulates NMDA-R subunit expression, and these changes are associated with a shift in the distribution of myocytes in individual Ca2+-mobilization sub-groups in vitro. Further, post-TNF exposure, NMDA-R agonists’ treatment induced Ca2+-dependent airway dilation in murine lung slice preparations, an effect that was prevented by co-treatment with inhibitors of nitric oxide synthase (NOS) or cyclooxygenase (COX). Taken together, we conclude that NMDA-R regulate HASM-mediated airway contraction and their role can be affected upon exposure to asthma-associated inflammatory mediators. Thus, NMDA-Rs are of relevance to mechanisms that determine airway narrowing and AHR associated with chronic respiratory diseases. / October 2015
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