Development of Novel Glucocorticoids for Use in Antibody-Drug Conjugates for the Treatment of Inflammatory Diseases.

Glucocorticoids (GCs) are widely used to treat a variety of autoimmune and inflammatory diseases; however, systemic delivery of GCs is associated with side effects that affect essentially every organ system, reflecting the nearly ubiquitous expression of the glucocorticoid receptor (GR). Targeted delivery of GCs to diseased tissues using antibody-glucocorticoid conjugates (GC-ADCs) offers a therapeutic alternative to overcome these adverse effects. Herein, we describe novel classes of GCs that exhibited greater potency than dexamethasone and budesonide, a 100-fold selectivity toward the GR over other nuclear receptors, and no in vitro safety liability in pharmacology assays (hERG, AMES) and that demonstrated a substantial reduction in tumor necrosis factor-α (TNF-α) release in mice challenged with lipopolysaccharide (LPS). The site-specific conjugated GC-ADCs via cathepsin-cleavable linkers were highly stable in plasma and specifically released GCs in antigen-positive cells, suggesting that these novel GCs can serve as ADC payloads to treat autoimmune and inflammatory diseases.

Budesonide use and misuse in sports: Elimination profiles of budesonide and metabolites after intranasal, high-dose inhaled and oral administrations.

Budesonide (BUD) is a glucocorticoid (GC) widely used in therapeutics. In sports, the World Anti-doping Agency (WADA) controls the use of GCs, and WADA-accredited laboratories use a reporting level of 30 ng/mL for 6ß-hydroxy-budesonide (6ßOHBUD) to detect the systemic administration of BUD. In the present work, we examined the urinary excretion profile of 6ßOHBUD, BUD, and 16α-hydroxy-prednisolone (16αOHPRED) after intranasal (INT), inhaled (INH) (at high doses) and oral administrations in male and female volunteers. BUD was administered to healthy volunteers using INT route (256 µg/day for three days, n = 4 males and 4 females), INH route (800 µg/day for three days, n = 4 males and 4 females, and 1600 µg/day for three days, n = 4 males) or oral route (3 mg, n = 8 females). Urine samples were collected before and after administration at different time periods, and were analyzed by liquid chromatography-tandem mass spectrometry. 6ßOHBUD and BUD concentrations were very low after INT treatment (0.0-7.1 and 0.0-8.1 ng/mL, respectively), and higher after INH treatments (0.0-35.4 and 0.0-48.3 ng/mL, respectively). For 16αOHPRED, elevated concentrations were detected after INT and INH treatments (2.6-66.4 and 3.4-426.5 ng/mL, respectively). Concentrations obtained following oral administration were higher than after therapeutic administrations (2.8-80.6, 1.5-36.1, and 10.4-532.2 ng/mL for 6ßOHBUD, BUD, and 16αOHPRED, respectively). After all administrations, concentrations were higher in males than in females. Results demonstrated that 6ßOHBUD is the best discriminatory marker and a reporting level of 40 ng/mL was found to be the best criterion to distinguish allowed from forbidden administrations of BUD.

Azo-reductase activated budesodine prodrugs for colon targeting.

Budesodine is a synthetic glurocorticoid that undergoes substantial first pass metabolism, limiting systemic exposure. Its use in treatment of inflammatory bowel disease would benefit from a targeting strategy that could lead to a local topical effect, improving safety and increasing anti-inflammatory efficacy. A two-step prodrug strategy involving azoreduction/cyclization that we developed previously for prednisolone is here applied with some variations to budesonide. The budesodine prodrugs were tested using an in vitro azoreductase assay simulating human colonic microflora. The kinetics of amino steroid ester cyclization and its pH dependence was also evaluated. The stability of the prodrugs systems in simulated human duodenal and gastric fluid was evaluated to determine the likelihood of intact intestinal transit. The propionic acid derived prodrug 3 undergoes rapid activation by Clostridium perfingens and its putative reduction product cyclizes with acceptable rapidity when synthesized independently. These properties of 3 suggest that it has potential in management of ulcerative colitis.

Bronchoprotection in conscious guinea pigs by budesonide and the NO-donating analogue, TPI 1020, alone and combined with tiotropium or formoterol.

BACKGROUND AND PURPOSE: Inhaled corticosteroids, anticholinergics and ß2-adrenoceptor agonists are frequently combined for treating chronic respiratory diseases. We examine the corticosteroid, budesonide, and novel NO-donating derivative, TPI 1020, against histamine- and methacholine-induced bronchoconstriction and whether they enhance the ß2-adrenoceptor agonist formoterol or muscarinic antagonist tiotropium in conscious guinea pigs. EXPERIMENTAL APPROACH: Dunkin-Hartley guinea pigs received inhaled histamine (3 mM) or methacholine (1.5 mM) and specific airway conductance (sG(aw)) was measured before and 15 or 75 min after treatment with budesonide, TPI 1020, tiotropium or formoterol alone or in combinations. KEY RESULTS: Formoterol (0.7-10 µM) and budesonide (0.11-0.7 mM) inhibited histamine-induced bronchoconstriction and tiotropium (2-20 µM) inhibited methacholine-induced bronchoconstriction by up to 70.8 ± 16.6%, 34.9 ± 4.4% and 85.1 ± 14.3%, respectively. Formoterol (2.5 µM) or tiotropium (2 µM) alone exerted small non-significant bronchoprotection. However, when co-administered with TPI 1020 0.11 mM, which alone had no significant effect, there was significant inhibition of the bronchoconstriction (45.7 ± 12.2% and 79.7 ± 21.4%, respectively). Co-administering budesonide (0.11 mM) with tiotropium (2 µM), which alone had no effect, also significantly inhibited the methacholine bronchoconstriction (36.5 ± 13.0%), but there was no potentiation of formoterol against histamine. The NO scavenger, CPTIO, prevented the bronchoprotection by SNAPand TPI 1020. CONCLUSIONS AND IMPLICATIONS: TPI 1020 potentiated the bronchoprotection by formoterol and tiotropium. Budesonide also enhanced the effects of tiotropium but not formoterol. Combination of TPI 1020 with a long-acting ß2-adrenoceptor agonist or muscarinic receptor antagonist may therefore be a more potent therapeutic approach for treatment of chronic respiratory diseases.

TPI 1020, a novel anti-inflammatory, nitric oxide donating compound, potentiates the bronchodilator effects of salbutamol in conscious guinea-pigs.

Inhaled corticosteroids are regularly co-administered with beta(2)-adrenoceptor agonists. This study evaluates in conscious guinea-pigs the bronchodilator effect, alone or combined with salbutamol, of TPI 1020, a novel anti-inflammatory corticosteroid and nitric oxide (NO) donor derived from budesonide. Guinea-pigs received inhaled histamine (3 mM) and specific airway conductance (sG(aw)) measured. Responses to histamine were measured before and on the next day 15 min after a 15 min inhalation of vehicle, salbutamol, TPI 1020, budesonide, the NO-donor, S-nitroso-N-acetylpenicillamine (SNAP), or combinations of these drugs. Salbutamol and TPI 1020 caused concentration-dependent bronchodilatation measured as inhibition of histamine-induced bronchoconstriction. TPI 1020-induced bronchodilatation was blocked by the guanylyl cyclise inhibitor, ODQ, indicating cGMP-dependence through released NO. While salbutamol at 80 microM did not exert significant bronchodilatation, significant inhibitions were observed when co-administered with TPI 1020, 0.11 and 0.33 mM. The combined effects of TPI 1020 and salbutamol lasted significantly longer than either drug alone. Inhaled budesonide was a weak bronchodilator and when co-administered with salbutamol there was enhanced bronchodilatation. Addition of the NO-donor, SNAP (0.1 mM), to the budesonide/salbutamol combination, also improved the inhibition of histamine-induced bronchoconstriction. This study has shown that TPI 1020 potentiates the bronchodilator activity of salbutamol, and their combination lasted longer than either drug administered individually. Both the corticosteroid and NO-releasing activities of TPI 1020 appear to be required for the potentiation of salbutamol. Combination of TPI 1020 with a beta(2)-adrenoceptor agonist may therefore be useful against acute bronchoconstriction episodes in asthma, and may offer an opportunity for reducing doses of inhaled beta(2)-adrenoceptor agonists.

Safety, pharmacodynamics and pharmacokinetics of TPI 1020 in smokers with asthma.

BACKGROUND: TPI 1020 is a novel compound with potential for anti-neutrophil effects. TPI 1020 exerts its effects by a dual mechanism of action involving corticosteroid activity and controlled donation of nitric oxide. OBJECTIVES: We assessed the safety, pharmacodynamic and pharmacokinetic activity of ascending doses of TPI 1020 compared to budesonide in asthma. METHODS: Smokers with mild asthma (n=27) were randomized to receive either 600mcg of TPI 1020 (n=13) or 400mcg of budesonide (n=14) bid for 2weeks followed by 1200 and 800mcg bid, respectively, for an additional week. RESULT: There was no serious adverse event and all but one adverse event were mild or moderate (severe headache with budesonide). Patients receiving TPI 1020 reported three-fold fewer treatment-emergent AEs (n=13) than those receiving budesonide (n=39). TPI 1020 had similar effects as budesonide on FEV(1), PEF, rescue medication, asthma scoring system, methacholine response, sputum eosinophils and exhaled NO. Sputum neutrophils (%) tended to decrease more with TPI 1020 (32.6% decrease versus 3.7% increase for budesonide); the decrease occurring only in patients with high neutrophils at baseline. A significant difference favoring TPI 1020 was noted for CRP. Budesonide caused a statistically significant decrease in 24h urinary free cortisol over 22days (median of 4.4-2.8mcg/ml, p=0.01) whereas TPI 1020 had no such effect (4.4-5.8mcg/ml), suggesting lower systemic corticosteroid exposure following TPI 1020 treatment. CONCLUSION: TPI 1020 appears safe in asthmatic smokers and warrants further investigation in respiratory conditions.

Comparative effects of inhaled budesonide and the NO-donating budesonide derivative, NCX 1020, against leukocyte influx and airway hyperreactivity following lipopolysaccharide challenge.

Lipopolysaccharide (LPS) inhalation (30 microg ml(-1), 1 h) caused airway hypereactivity (AHR) to histamine (1 mM, 20 s) 1 h later in conscious guinea-pigs. Bronchoalveolar lavage fluid (BALF) levels of neutrophils, myeloperoxidase (MPO) and protein were elevated whereas nitric oxide (NO) metabolites were reduced 1 h after LPS compared with saline challenge. 24 h after LPS, there was no AHR, but BALF neutrophils, eosinophils, macrophages, MPO, protein and NO metabolites were all raised. Budesonide (0.7 mM) and a molar equivalent concentration of the NO-donating budesonide derivative, NCX 1020, were inhaled (15 min) at 24 h and 45 min before LPS. The only change produced by budesonide was to reduce eosinophil influx at 24 h after LPS, compared with vehicle treated animals. NCX 1020, however, blocked AHR and reduced neutrophils (1 and 24 h) and MPO (1 and 24 h), while NO levels were raised at 1 and reduced at 24 h after LPS. The combined inhalation before LPS of the NO donor, SNAP (1.4 mM), with budesonide (0.7 mM) blocked the AHR to histamine and significantly reduced neutrophils (1 and 24 h) and MPO (1 and 24 h), while NO levels were raised at 1 h after LPS. Thus, NO and a corticosteroid co-administered as NCX 1020 or budesonide with a NO donor, have an additive effect against LPS-induced inflammatory responses and may have value in the treatment of neutrophil-driven airways disease such as COPD.

Biotransformation in vitro of the 22R and 22S epimers of budesonide by human liver, bronchus, colonic mucosa and skin.

The pharmacological effects of glucocorticoids are greatly influenced by their pharmacokinetic properties. In the present report, the in vitro biotransformation of the 22R and 22S epimers of the topical steroid budesonide was studied in the S-9 fraction of human liver, bronchus, skin and colonic mucosa. The disappearance of unchanged epimers of budesonide was measured during 90 min of incubation by high performance liquid chromatography. The rate of disappearance was high in human liver while little biotransformation occurred in bronchial tissue and colonic mucosa, and none was detected in the skin. A marked decay of the initial concentration of unchanged budesonide epimers was noticed after 2 h incubation in cultured human hepatocytes, while only a small decrease was observed after 24 h incubation in cultured human airway smooth muscle cells and BEAS-2B cells. The 22R epimer of budesonide suffered greater in vitro biotransformation than the 22S epimer in human hepatic, bronchial and colonic tissues. These findings extend those of other studies, and confirm that the high therapeutic ratio of budesonide is due to negligible local biotransformation combined with high level of liver metabolism for locally absorbed budesonide.

Improved effects of novel glucocorticosteroids on immune-induced epithelial pathophysiology.

Glucocorticosteroids are a mainstay therapy in inflammatory bowel disease and other chronic inflammatory conditions. However, severe systemic side effects are associated with their long-term use. The new generation of glucocorticosteroids have a high degree of topical activity with reduced systemic effects due to rapid metabolism. We previously described an in vitro model of inflammation in which monolayers of the human T84 colonic epithelial cell line displayed altered ion secretion and increased permeability after coculture with endotoxin-activated monocytes/macrophages (MPhi). Here, we tested the effects of budesonide and two novel analogs, D5519 and S1316, on MPhi-induced epithelial changes. Filter-grown T84 monolayers were cocultured with activated MPhi and single daily doses of drug were added to the luminal (physiological) side of the monolayer. Basal and stimulated epithelial ion transport [baseline short-circuit current (Isc) and DeltaIsc to forskolin, respectively] and barrier (transepithelial resistance) parameters were measured 48 h later in Ussing chambers. D5519, S1316, and budesonide (10(-7) to 10(-9) M) dose dependently inhibited the MPhi-induced epithelial abnormalities, restoring normal resistance, decreasing the elevated baseline Isc, and improving the reduced Isc response to forskolin. Of the drugs tested, D5519 was consistently the most potent and effective in inhibiting the MPhi-induced epithelial irregularities. Coupled with a further improvement in their rate of hepatic inactivation, our findings indicate that the novel steroids, particularly D5519, will be a valuable addition to current treatment strategies for inflammatory bowel disease and other chronic inflammatory conditions.

Comparative effects of anti-inflammatory corticosteroids in human bone-derived osteoblast-like cells.

While effects of inhaled corticosteroids on serum markers of bone metabolism in normal and asthmatic subjects have been reported, there are little data on the direct effects of these corticosteroids on end-organs such as bone. The results presented here compare the effects of budesonide and its epimers (22S- and 22R-budesonide), fluticasone and dexamethasone on growth and differentiation of cultured human bone cells. Osteoblast-like cells were cultured from human foetal bone chips grown to confluence and used at first subculture. At concentrations of 10(-11)-10(-7) M each corticosteroid (CS) caused a dose-dependent decrease in [3H]thymidine incorporation into deoxyribonucleic acid (DNA), median effective concentration (EC50): fluticasone (0.06 nM) >22R (0.26 nM) >22S (0.4 nM) >budesonide (0.47 nM) >dexamethasone (1.5 nM). Each CS resulted in a dose-dependent increase in alkaline phosphatase activity, EC50: fluticasone (0.14 nM) >22R (0.2 nM)=22S (0.2 nM) >budesonide (0.4 nM) >dexamethasone (1.6 nM). The 1,25 dihydroxyvitamin D3 (1,25(OH)2D3)-stimulated osteocalcin production was decreased in the presence of each CS, EC50: fluticasone (0.02 nM) >22S (0.1 nM) >22R (0.2 nM) >budesonide (1.0 nM) >dexamethasone (1.8 nM). In human bone cells the potencies of fluticasone and budesonide in relation to dexamethasone are not dissimilar to those derived from human lymphocytes in vitro.