The effect of the bronchodilator salbutamol on lung function in post cardio-thoracic surgical patients who are over 50 years of age and without predisposing respiratory illnesses, as measured by the peak-expiratory-flow-metre device /

Carr, Aura.

Unknown Date

Thesis (MNursing (Advanced Practice))--University of South Australia, 1996

Bronchodilator agents.

Pulmonary pharmacology.

Immunomodulatory effects of opioids

Odunayo, Adesola. DeClue, Amy.

January 2010

The entire dissertation/thesis text is included in the research.pdf file; the official abstract appears in the short.pdf file (which also appears in the research.pdf); a non-technical general description, or public abstract, appears in the public.pdf file. Title from PDF of title page (University of Missouri--Columbia, viewed on July 13, 2010). Thesis advisor: Amy DeClue. "May 2010" Includes bibliographical references.

Pulmonary morphometric histopathology of saline or paraquat-exposed rats treated with the collagen inhibitor dehydroproline

Onyeama, Henry Patrick.

January 1984

Call number: LD2668 .T4 1984 O59 / Master of Science

Pulmonary pharmacology.

Lungs--Diseases.

Paraquat--Toxicology.

Masters theses

Monocrotaline toxicity and pulmonary arteries.

Shubat, Pamela Jane.

January 1988

Monocrotaline is a pyrrolizidine alkaloid found in plants implicated in livestock and human poisoning. Laboratory rats given monocrotaline develop pulmonary hypertension and right heart hypertrophy in the weeks following administration of the chemical. Lung weight increases and right heart hypertrophy correlate with increased pulmonary artery pressure. Rats which consumed monocrotaline drinking water (20 mg/l) for only 4 days developed significant increases in lung and heart weights 14 days after exposure began. This exposure was equivalent to a dose of 15 mg/kg. Other treatment combinations of time (0-10 days exposure) and monocrotaline concentration (5-60 mg/l in drinking water) were tested. The accumulative dose calculated for each of the treatment combinations which produced toxicity was in the range of 15 to 20 mg/kg. Monocrotaline injury appears to be cumulative, but organ weight increases reverse once exposure is stopped. As pulmonary hypertension develops and pulmonary arteries hypertrophy, the force with which isolated pulmonary artery segments contract decreases. This is a loss of efficacy rather than potency to the contracting agents KCl, norepinephrine, and 5-hydroxytryptamine. Relaxation of arteries under conditions of potassium-return (a measure of Na⁺/K⁺ ATPase activity) was also altered by monocrotaline treatment. In vivo monocrotaline treatment had little effect on the force of K⁺-return relaxation. However, the rate at which arteries relaxed was significantly decreased following 4 days ingestion of monocrotaline drinking water (20 mg/l). In vitro ouabain treatment and endothelial injury also decreased the rate of K⁺-return relaxation. Another Na⁺/K⁺ ATPase activity, ⁸⁶Rb⁺ uptake, was decreased following monocrotaline treatment only when 5-hydroxytryptamine was present and only uptake associated with the endothelium was affected. These studies utilized a very low exposure to monocrotaline (4 days ingestion of 20 mg/l monocrotaline drinking water or 15 mg/kg) to produce toxicity in rats. Monocrotaline-induced toxicity measured 20 days after treatment included right heart and lung hypertrophy and decreased contractions of isolated pulmonary arteries. Monocrotaline treatment decreased the rate of Na⁺/K⁺ ATPase-dependent relaxation of isolated pulmonary arteries 4 days after treatment began.

Pyrrolizidines.

Pulmonary artery -- Effect of drugs on.

Pulmonary pharmacology.

Heart -- Effect of chemicals on.

THE EFFECT OF PIRFENIDONE ON CHRYSOTILE ASBESTOS-INDUCED PULMONARY FIBROSIS IN THE HAMSTER (ANTI-INFLAMMATORY DRUG)

Grimm, Scott Wayne, 1961-

January 1986

No description available.

Lungs -- Diseases -- Treatment.

Lungs -- Dust diseases.

Pulmonary pharmacology.

Aerosolized bronchodilator therapy in infants with bronchopulmonary dysplasia: comparison between metered dose inhaler, jet nebuliser and ultrasonic nebuliser.

January 1996

by Lam Kuo. / Year shown on spine: 1997. / Thesis (M.Phil.)--Chinese University of Hong Kong, 1996. / Includes bibliographical references (leaves 107-121). / Acknowledgments / List of Abbreviations / Summary / List of Contents / List of Tables / List of Figures / Chapter Chapter 1 --- Introduction and the objectives of the study --- p.1-6 / Chapter Chapter 2 --- Overviews of Bronchopulmonary Dysplasia (BPD) and bronchodilator therapy -- a literature review --- p.7-29 / Chapter 2.1 --- Overview of Bronchopulmonary Dysplasia (BPD) --- p.7-9 / Chapter 2.2. --- Bronchodilator therapy --- p.10-18 / Chapter 2.2.1 --- Therapeutic value on infants with Bronchiolitis / Chapter 2.2.2. --- Therapeutic value on infants with Bronchopulmonary Dysplasia (BPD) / Chapter 2.3. --- "Three modes of aerosol delivery devices --jet nebuliser , ultrasonic nebuliser and metered dose inhaler" --- p.18-29 / Chapter 2.3.1. --- Jet nebuliser / Chapter 2.3.2. --- Ultrasonic nebuliser / Chapter 2.3.3. --- Metered dose inhaler / Chapter 2.3.4. --- Comparison of the therapeutic efficiency between jet nebuliser， ultrasonic nebuliser and Metered dose inhaler / Chapter 2.3.4.a. --- Comparison of particle size / Chapter 2.3.4.b. --- Comparison of aerosol deposition / Chapter 2.3.4.c. --- Comparison of pulmonary function / Chapter Chapter 3 --- Pulmonary function test in neonates --a literature review --- p.30-40 / Chapter 3.1. --- Overview of pulmonary function test in neonates --- p.30 / Chapter 3.2. --- Assessment of pulmonary function test in neonates --- p.31-40 / Chapter 3.2.1. --- Pulmonary mechanics / Chapter 3.2.1.a. --- Lung compliance / Chapter 3.2.1.b. --- Airway resistance / Chapter 3.2.1.c. --- Functional residual capacity (FRC) / Chapter Chapter 4 --- Subjects and methods --- p.41-48 / Chapter 4.1. --- Subjects --- p.41-42 / Chapter 4.2. --- Methods --- p.42-48 / Chapter 4.2.1. --- Delivery of Salbutamol aerosol / Chapter 4.2.1.1. --- Spontaneously breathing non-ventilated infants (group 1) / Chapter 4.2.1.2. --- Ventilator-dependent infants (group 2) / Chapter 4.2.2. --- Monitoring the clinical parameters / Chapter 4.2.3. --- Measurement of pulmonary function / Chapter 4.2.4. --- Statistics / Chapter Chapter 5 --- Results --- p.49-53 / Chapter 5.1. --- Clinical parameters --- p.50-51 / Chapter 5.2. --- Pulmonary function tests --- p.51-53 / Chapter Chapter 6 --- Discussion --- p.54-61 / Chapter 6.1. --- Non-ventilated group --- p.55-58 / Chapter 6.2. --- Ventilated group --- p.58-61 / Chapter Chapter 7 --- Conclusion --- p.62-63 / Tables and Figures / References

Respiratory therapy for newborn infants

Pulmonary pharmacology

Bronchopulmonary Dysplasia

Bronchopulmonary Dysplasia--therapy

Aerosols--Therapeutic use

Bronchodilator Agents--Therapeutic use

New highly effective dry powder tobramycin formulations for inhalation in the treatment of cystic fibrosis / Nouvelles formulations à poudre sèche pour inhalation à base de tobramycine pour le traitement de la mucoviscidose

Pilcer, Gabrielle

27 October 2008

Local delivery of medication to the lung is highly desirable as the principal advantages include reduced systemic side effects and higher dose levels of the applicable medication at the site of drug action. This administration could be particularly useful for patients with specifically chronic pulmonary infections or pulmonary diseases, such as cystic fibrosis, asthma or lung cancer.<p>In order to deliver a high dose range of medication for highly-dosed drugs such as antibiotics, “carrier-free” DPI formulations of tobramycin were developed with the aim of minimizing the use of excipients. Briefly, dry powders were prepared by spray drying various suspensions of tobramycin in isopropanol.<p><p>First, as particle size is a key parameter in defining drug deposition in the lungs, the new Spraytec® laser diffraction method specifically modified for measuring the PSD of aerosolized drug was evaluated. The dispersion properties of various dry powder formulations were investigated using different laser diffraction and impaction apparatuses at different flow rates and using different inhalator devices. Different correlations between geometric and aerodynamic size data were demonstrated in this study. As a potential application, for the flow rate, the different inhalation devices and the drug formulations examined, the tobramycin fine particle fraction could be predicted from measurements obtained from the Spraytec® using linear relationships. Correlations (R² > 0.9) between the MMAD and the percentage of particles with a diameter below 5 µm could be demonstrated between the results obtained from the laser diffraction technique and the impaction method. Consequently, the Spraytec® laser diffraction technique was proved to be an important tool for initial formulation and process screening during formulation development of DPIs.<p><p>In order to modify the surface properties of the raw tobramycin powder, different powder compositions were formulated with the aim of studying the influence of the concentration of tobramycin in drug suspensions used for spray-drying, the lipid film composition (cholesterol:Phospholipon ratio) and the coating level (in percentage) on the physicochemical and aerodynamic characteristics of the antibiotic.<p>The results indicated that the application of a lipid coating around the active particles allowed an improvement in particle dispersion from the inhalator, decreasing raw powder agglomeration and thus enhancing drug deposition deep in the lungs. Moreover, these results seemed to be influenced by the amount and composition of the lipids in the formulations. The evaluation of the influence of the coating level showed that the deposition of only 5% w/w lipids (on a dry basis) was sufficient to improve particle dispersion properties during inhalation. The FPF, which is around 36% for the uncoated micronized tobramycin, was increased to up to about 68% for the most effective lipid-coated formulation. Of particular importance, these results revealed the need to add sufficient amounts of covering material in order to significantly modify the particle surface properties and reduce their tendency to agglomeration, while limiting the lipid level in the formulations in order to avoid any undesirable sticking and to allow the delivery of more of the active drug to the deep lung. <p><p>Another approach used to modify the surface properties of raw tobramycin was to coat the micronized particles with nanoparticles of the drug, produced by high pressure homogenization. The evaluation of the influence of the level of nanoparticle coating of the micronized particles showed that the presence of nanoparticles in the formulations improved the particle dispersion properties during inhalation. One microparticle was completely covered with a single layer or several layers of nanoparticles, in function of the percentage of nanoparticles in the mixture. Coating the fine drug particles with particles in the nanometer range was believed to reduce Van Der Waals forces and powder agglomeration. These various layers of nanoparticles also allowed a decrease in the cohesion of the powder by improving the slip between the particles.<p>On the other hand, suspensions containing solely nanoparticles were spray dried with various concentrations of surfactant in order to produce easily dispersible and reproducible micron-size agglomerates of nanoparticles during inhalation. The evaluation of the influence of the concentration of surfactant showed that deposition of only 2% w/w (on a dry basis) of Na glycocholate is sufficient to improve particle dispersion properties during inhalation. Consequently, the use of nanoparticles in dry powder formulations increased the FPF from 36% for the uncoated micronized tobramycin to about 61% for this latter formulation.<p>To modify the balance between the different forces of interactions without the need for any excipient, the influence of formulation components on the aerosolization characteristics of spray-dried tobramycin through the use of various proportions of water in the solvent used to prepare initial suspensions was investigated. These results showed that it is possible to modify the surface properties of the particles by coating the particles of drug with a homogeneously distributed film of the active compound dissolved in a solvent system containing a mixture of different solvents such as isopropanol and water. During nebulization of the suspension, droplets are composed of one or more particles in solid state surrounded with solvent containing the dissolved drug. It is hypothesized that during the drying step, dissolved tobramycin forms a coating of the amorphous drug around particles in suspension. The coating of drug particles can thus be used as an alternative approach that permits the modification of the surface properties of the particles, increasing the flowability, the desagglomeration tendency and the fine particle fraction deposited in the deep lung. So, the evaluation of the influence of the water content of the suspensions and the effect of the inlet temperature during spray-drying showed that the addition of 2% water v/v is sufficient to improve particle dispersion during inhalation. Of particular interest, as tobramycin is a very hygroscopic drug, the addition of water turned out to be a critical step. It was thus important to add a small amount of water to the solvent system and to process the drying step at a high temperature to produce formulations containing solely the active drug and showing a FPF of up to 50%.<p><p>Moreover, stability studies demonstrated that these optimized formulations (lipid-coated formulation, nanoparticle formulation and amorphous drug-coated formulation) were stable over a long time period at various ICH temperature and relative humidity storage conditions (25°C/60% RH, 30°C/65% RH and 40°C/75% RH). The formulations were shown to keep their crystalline state, initial PSD, redispersion characteristics and deposition results for more than twelve months.<p><p>In order to confirm these encouraging results, two optimized formulations (one with a lipid coating and another with amorphous drug coating) were selected and compared to the only commercially available tobramycin formulation for inhalation, Tobi® (nebulizer solution), by performing a combined in vivo scintigraphic and pharmacokinetic evaluation of tobramycin DPIs in nine CF patients.<p>In comparison with Tobi®, it was estimated that lung deposition, expressed as a percentage of the nominal dose, was 7.0 and 4.5 times higher for the lipid-coated and amorphous tobramycin-coated formulations, respectively. Moreover, the pharmacokinetic data, adjusted to the same drug dose as that of the Tobi® deposited in the lungs, showed that the AUC values were found to be 1.6 times higher for Tobi® than for DPI formulations. So this evaluation confirmed the superiority of dry powder formulations in terms of drug deposition and reduced systemic exposure in comparison with the conventional comparator product, Tobi®.<p><p>Thus, these new and orginal tobramycin DPI formulations based on the use of very low excipient levels and presenting very high lung deposition properties, were shown to offer very good prospects for improving the delivery of drugs to the pulmonary tract and to the widest possible patient population. <p><p> / Doctorat en Sciences biomédicales et pharmaceutiques / info:eu-repo/semantics/nonPublished

Sciences pharmaceutiques

Powders (Pharmacy)

Respiratory therapy

Tobramycin

Cystic fibrosis -- Chemotherapy

Pulmonary pharmacology

Poudres (Pharmacie)

Inhalothérapie

Tobramycine

Mucoviscidose -- Chimiothérapie

Pharmacologie pulmonaire

lipides

nanoparticules

mucoviscidose

atomisation

poudre sèche pour inhalation

administration pulmonaire

nanoparticles/antibiotique

spray drying

lipids

cystic fibrosis

pulmonary delivery

dpi

antibiotic