Glucocorticoid-Induced Exacerbation of Mycobacterial Infection Is Associated With a Reduced Phagocytic Capacity of Macrophages.

Glucocorticoids are effective drugs for treating immune-related diseases, but prolonged therapy is associated with an increased risk of various infectious diseases, including tuberculosis. In this study, we have used a larval zebrafish model for tuberculosis, based on Mycobacterium marinum (Mm) infection, to study the effect of glucocorticoids. Our results show that the synthetic glucocorticoid beclomethasone increases the bacterial burden and the dissemination of a systemic Mm infection. The exacerbated Mm infection was associated with a decreased phagocytic activity of macrophages, higher percentages of extracellular bacteria, and a reduced rate of infected cell death, whereas the bactericidal capacity of the macrophages was not affected. The inhibited phagocytic capacity of macrophages was associated with suppression of the transcription of genes involved in phagocytosis in these cells. The decreased bacterial phagocytosis by macrophages was not specific for Mm, since it was also observed upon infection with Salmonella Typhimurium. In conclusion, our results show that glucocorticoids inhibit the phagocytic activity of macrophages, which may increase the severity of bacterial infections like tuberculosis.

Realization of polyaspartamide-based nanoparticles and in vivo lung biodistribution evaluation of a loaded glucocorticoid after aerosolization in mice.

In this study, novel polymeric nanoparticles (NPs) were developed and their potential as carriers for beclomethasone dipropionate (BDP) into the lung after aerosolization was demonstrated by in vivo studies in mice. In particular, these NPs were obtained starting from two polyaspartamide-based copolymers which were synthesized by chemical reaction of α,ß-poly(N-2-hydroxyethyl)-dl-aspartamide (PHEA) and its pegylated derivative (PHEA-PEG2000) with poly(lactic acid) (PLA). To obtain nanosized particles, the high pressure homogenization (HPH)-solvent evaporation method was followed by using an organic phase containing both PHEA-PLA and PHEA-PEG2000-PLA (at a weight ratio equal to 1:1), lactose as cryoprotectant and no surfactant was adopted. PHEA-PLA/PHEA-PEG2000-PLA NPs were characterized by a quite spherical shape, ζ potential slightly negative, and size lower than 50 and 200nm, respectively, for empty and BDP-loaded NPs. In vivo biodistribution of BDP and its metabolites in various lung compartments, i.e. bronchoalveolar lavage fluid (BALF), alveolar macrophages (MPG) obtained from BALF, and lung tissue, was carried out at 3h post-administration in mice by aerosolization of BDP-loaded NPs or free BDP (commercial formulation, Clenil(®)) at the dose of 0.5mg/kg BDP. Results demonstrated that BDP entrapped into NPs reached all analyzed lung compartments and were internalized by both alveolar MPG and respiratory epithelial cells, and detected amounts were comparable to those of Clenil-treated mice. Moreover, the entrapment into NPs protects the drug from the enzymatic hydrolysis, allowing a significant lower amount of beclomethasone (BOH) into the lung tissue and BALF than that obtained after Clenil administration.

Influence of oral beclomethasone dipropionate on early non-infectious pulmonary outcomes after allogeneic hematopoietic cell transplantation: results from two randomized trials.

Early non-infectious pulmonary complications represent a significant cause of mortality after hematopoietic cell transplantation (HCT). We tested the hypothesis that oral beclomethasone dipropionate (BDP) is effective for preventing early non-infectious pulmonary complications after allogeneic HCT. We retrospectively reviewed the medical records of 120 patients, 60 in each treatment arm, to identify non-infectious and infectious pulmonary events and pulmonary function test results from all patients who participated in two randomized trials of oral BDP for treatment of acute gastrointestinal GVHD. 17-Beclomethasone monopropionate (17-BMP), the active metabolite of BDP, was evaluated in blood from the right atrium in four patients. Thirty-three of 42 (79%) placebo-treated patients experienced a decrease of the DL(CO) from pretransplant to day 80 after transplant, compared with 27 of 49 (55%) BDP-treated patients (P=0.02). In the first 200 days after randomization, there were no cases of non-infectious pulmonary complications in BDP-treated patients, vs four cases among placebo-treated patients (P=0.04). Levels of 17-BMP were detected in atrial blood at steady state. Delivery of a potent glucocorticoid such as 17-BMP to the pulmonary artery after oral dosing of BDP may be useful in modulating pulmonary inflammation and preventing the development of non-infectious pulmonary complications after allogeneic HCT.

In vitro metabolism of beclomethasone dipropionate, budesonide, ciclesonide, and fluticasone propionate in human lung precision-cut tissue slices.

BACKGROUND: The therapeutic effect of inhaled corticosteroids (ICS) may be affected by the metabolism of the drug in the target organ. We investigated the in vitro metabolism of beclomethasone dipropionate (BDP), budesonide (BUD), ciclesonide (CIC), and fluticasone propionate (FP) in human lung precision-cut tissue slices. CIC, a new generation ICS, is hydrolyzed by esterases in the upper and lower airways to its pharmacologically active metabolite desisobutyryl-ciclesonide (des-CIC). METHODS: Lung tissue slices were incubated with BDP, BUD, CIC, and FP (initial target concentration of 25 microM) for 2, 6, and 24 h. Cellular viability was assessed using adenosine 5'-triphosphate content and protein synthesis in lung slices. Metabolites and remaining parent compounds in the tissue samples were analyzed by HPLC with UV detection. RESULTS: BDP was hydrolyzed to the pharmacologically active metabolite beclomethasone-17-monopropionate (BMP) and, predominantly, to inactive beclomethasone (BOH). CIC was hydrolyzed initially to des-CIC with a slower rate compared to BDP. A distinctly smaller amount (approximately 10-fold less) of fatty acid esters were formed by BMP (and/or BOH) than by BUD or des-CIC. The highest relative amounts of fatty acid esters were detected for BUD. For FP, no metabolites were detected at any time point. The amount of drug-related material in lung tissue (based on initial concentrations) at 24 h was highest for CIC, followed by BUD and FP; the smallest amount was detected for BDP. CONCLUSION: The in vitro metabolic pathways of the tested ICS in human lung tissue were differing. While FP was metabolically stable, the majority of BDP was converted to inactive polar metabolites. The formation of fatty acid conjugates was confirmed for BMP (and/or BOH), BUD, and des-CIC.

Direct measurement of BDP and 17-BMP in bronchial and peripheral lung tissue after inhalation of HFA- vs CFC-driven aerosols.

Indirect assessments have shown a superior lung deposition of HFA-BDP (Ventolair/Qvar) compared to CFC-BDP (Aerobec). The aim of this study was to assess the concentrations of BDP and its metabolite 17-BMP in airways and peripheral tissue from resected lung specimens after inhalation of these BDP formulations. Immediately prior to surgery for lung cancer, 10 patients inhaled 1000 microg of either CFC-BDP (n = 5) or HFA-BDP (n = 5) Mouthwash was collected after inhalation, and serum before, during, and after surgery. There was no significant difference between CFC and HFA in the concentration of 17-BMP in bronchi (median, 4365 vs 4121 pg/g tissue). After CFC, concentrations of 17-BMP were lower in peripheral tissue (1424 vs 2089 pg/g; ANCOVA, p = 0.001) and in serum taken immediately after inhalation (688 vs 1219 pg/ml, p < 0.01). Furthermore, the CFC group showed a higher concentration of BDP in the mouthwash (17,660 vs 1320 ng/ml, p < 0.05), but the concentration of 17-BMP was lower (452 vs 1028 ng/ml, n.s.). These findings indicate a predominantly peripheral deposition of HFA-BDP, in line with previous data. They also provide evidence for a faster uptake and metabolism of HFA-BDP, probably because BDP is dissolved in HFA and has a smaller particle size distribution than the CFC suspensions.

The nonspecific esterases of human mononuclear leukocytes metabolize arylamine carcinogens and steroids esters.

The presence of non-specific esterases in various leukocyte subfractions of whole blood is well established, but no endogenous substrates or function for these esterases have been identified. Here we report on the metabolism of N-acetoxy-2-acetylaminofluorene (NA-AAF) and beclomethasone-17-21-dipropinate (BDP) in viable human mononuclear leukocytes (HML). Conversion of NA-AAF to DNA binding intermediates and BDP to beclomethasone-17-monopropionate by a common esterase was demonstrated and then further characterized by a broad spectrum of effectors including well-established inhibitors and substrates for the nonspecific esterases. Two esters, beta estradiol-17-propionate and alpha naphtyl propionate, competitively inhibited this esterase activity. Together, these data identify at least one isozyme of A- or B-classes of HML nonspecific esterases as being responsible for the metabolism of NA-AAF and BDP. That HML nonspecific esterases may be functionally involved in arylamine carcinogenes (i.e. as it may relate to immune function) and in the endogenous production of steroids from their naturally occurring esters emphasizes the importance of continuing their characterization.

Beclomethasone dipropionate. A reappraisal of its pharmacodynamic properties and therapeutic efficacy after a decade of use in asthma and rhinitis.

Inhaled beclomethasone dipropionate is now well established in the management of asthma. Studies conducted over the last decade, and since the drug was previously reviewed in the Journal, have confirmed that inhaled beclomethasone dipropionate 400 to 800 micrograms daily can reduce the need for oral maintenance corticosteroids in the majority of asthmatic patients requiring such therapy, and that increasing the dosage to 2000 micrograms daily may provide additional clinical benefit in some patients unresponsive to usual therapeutic dosages. Follow-up over a period of several years has confirmed that the initial response to inhaled beclomethasone can be maintained in most patients. Recent studies indicate that beclomethasone dipropionate 400 micrograms daily is equally effective when administered in 2 or 4 divided doses in patients with stable asthma, but it is likely that the lower frequency of administration will be less effective when the asthma is unstable. Recent studies have established the usefulness and good tolerability of intranasal beclomethasone dipropionate in the treatment of perennial and seasonal rhinitis, where the drug has been shown to be more effective than intranasal sodium cromoglycate and similar in efficacy to flunisolide. Nasal polyps decrease in size during continuous treatment with intranasal beclomethasone dipropionate, but enlarge again during periods of respiratory infection. After a decade of treatment with inhaled and intranasal beclomethasone dipropionate, there is no evidence that the drug damages the tracheobronchial lining or the nasal mucosa. Thus, the initial promise of beclomethasone dipropionate has been fulfilled. It has had an important role in asthma therapy over the past decade, which will continue into the future.

Beclomethasone dipropionate inhaler: a review of its pharmacology, therapeutic value and adverse effects. I: Asthma.

Beclomethasone dipropionate is a topically active corticosteroid used as an adjuvant in the control of chronic asthma when given by inhalation as an aerosol. It is not intended for treatment of acute attacks. It appears that the main difference between beclomethasone dipropionate and other corticosteroids previously used by inhalation is its high topical activity together with a lower systemic activity due to metabolic inactivation of the swallowed portion of the dose. Clinical experience has shown that at doses of 200 to 600mug daily, beclomethasone dipropionate inhaler is preferable to oral corticosteroids, because of lack of side-effects, when adult patients and children who are inadequately controlled by full doses of sodium cromoglycate and bronchodilators, are first considered to need maintenance corticosteroids. Inhaled beclomethasone dipropionate can allow a worthwhile reduction in maintenance doses of systemic corticosteroids in many patients already receiving these drugs and can replace systemic steroids entirely in some patients, particularly when their initial dose of steroids is less than 10mg daily of prednisone or its equivalent. Substitution should be attempted when the patient's asthma is well controlled on their usual doses of systemic steroids and full doses of other adjuvant therapy. Withdrawal of systemic corticosteroids should be performed slowly and carefully. Because recovery from impaired adrenocortical function caused by prolonged systemic steroid therapy is usually slow, special care is necessary for 9 to 12 months after transfer to beclomethasone dipropionate aerosol until the hypothalamo-pituitary-adrenal axis has sufficiently recovered to cope with emergencies such as trauma, surgery, severe infections or an acute attack of asthma. It is essential that additional therapy including high doses of systemic corticosteroids be used immediately to control any acute exacerbation of asthma which occurs during maintenance therapy with beclomethasone dipropionate aerosol. Tests of adrenal function suggest that beclomethasone dipropionate at dosages of 400 to 800 mug daily has little or no adverse effect. The most common side-effect associated with the continuous use of beclomethasone dipropionate inhaler has been oropharyngeal candidiasis, which appears to be dose-related and more common in women than in men. Systemic steroid withdrawal effects, like being generally unwell, and exacerbation of underlying allergic diseases such as allergic rhinitis, have been reported after substitution of beclomethasone dipropionate inhaler for systemic steroids. However, systemic withdrawal effects seldom occur if systemic steroids are withdrawn slowly.