Cristina Carreño

Characterization of Aclidinium Bromide, a Novel Inhaled Muscarinic Antagonist, with Long Duration of Action and a Favorable Pharmacological Profile

Aclidinium bromide is a novel potent, long-acting inhaled muscarinic antagonist in development for the treatment of chronic obstructive pulmonary disease. Aclidinium showed subnanomolar affinity for the five human muscarinic receptors (M1–M5). [3H]Aclidinium dissociated slightly faster from M2 and M3 receptors than [3H]tiotropium but much more slowly than [3H]ipratropium. Its association rate for the M3 receptor was similar to [3H]ipratropium and 2.6 times faster than [3H]tiotropium. Residence half-life of [3H]aclidinium at the M2 receptor was shorter than at the M3 receptor, demonstrating kinetic selectivity for the M3 receptor. In isolated guinea pig trachea, aclidinium showed comparable potency to ipratropium and tiotropium, faster onset of action than tiotropium, and duration of action similar to tiotropium and significantly longer than ipratropium. Nebulized aclidinium inhibited bronchoconstriction induced by acetylcholine in guinea pigs in a concentration-dependent manner with an onset of action faster than tiotropium. Duration of action of aclidinium (t1/2 = 29 h) was much longer than ipratropium (8 h) but shorter than tiotropium (64 h). In dogs, aclidinium induced a smaller and more transient increase in heart rate than tiotropium at comparable supratherapeutic doses. Therefore, under these conditions, aclidinium showed a greater therapeutic index than tiotropium (4.2 versus 1.6). These results indicate that aclidinium is a potent muscarinic antagonist with a fast onset of action, a long duration of effect, and a favorable cardiovascular safety profile.

Effects of Aclidinium Bromide in a Cigarette Smoke–Exposed Guinea Pig Model of Chronic Obstructive Pulmonary Disease

Long-acting muscarinic antagonists are widely used to treat chronic obstructive pulmonary disease (COPD). In addition to bronchodilation, muscarinic antagonism may affect pulmonary histopathological changes. The effects of long-acting muscarinic antagonists have not been thoroughly evaluated in experimental models of COPD induced by chronic exposure to cigarette smoke (CS). We investigated the effects of aclidinium bromide on pulmonary function, airway remodeling, and lung inflammation in a CS-exposed model of COPD. A total of 36 guinea pigs were exposed to CS and 22 were sham exposed for 24 weeks. Animals were nebulized daily with vehicle, 10 μg/ml, or 30 μg/ml aclidinium, resulting in six experimental groups. Pulmonary function was assessed weekly by whole-body plethysmography, determining the enhanced pause (Penh) at baseline, after treatment, and after CS/sham exposure. Lung changes were evaluated by morphometry and immunohistochemistry. CS exposure increased Penh in all conditions. CS-exposed animals treated with aclidinium showed lower baseline Penh than untreated animals (P = 0.02). CS induced thickening of all bronchial wall layers, airspace enlargement, and inflammatory cell infiltrate in airways and septa. Treatment with aclidinium abrogated the CS-induced smooth muscle enlargement in small airways (P = 0.001), and tended to reduce airspace enlargement (P = 0.054). Aclidinium also attenuated CS-induced neutrophilia in alveolar septa (P = 0.04). We conclude that, in guinea pigs chronically exposed to CS, aclidinium has an antiremodeling effect on small airways, which is associated with improved respiratory function, and attenuates neutrophilic infiltration in alveolar septa. These results indicate that, in COPD, aclidinium may exert beneficial effects on lung structure in addition to its bronchodilator action.

Pyrazine-based Syk kinase inhibitors.

A series of aminopyrazines as inhibitors of Syk kinase activity and showing inhibition of LAD2 cells degranulation is described. Optimization of the carboxamide motif with aminomethylpiperidines provided high potency inhibiting Syk but low cellular activity. Amides of cis and trans adamantanol showed good inhibitory activity against Syk as well as remarkable activity in LAD2 cells degranulation assay.

Highly potent aminopyridines as Syk kinase inhibitors.

A novel class of potent Syk inhibitors has been developed from rational design. Highly potent aminopyridine derivatives bearing a 4-trifluoromethyl-2-pyridyl motif and represented by compound 13b IC(50): 0.6 nM were identified. Substitution by a 2-pyrazinyl motif and SAR expansion in position 4 of the central core provided diverse potent non-cytotoxic Syk inhibitors showing nanomolar activity inhibiting human mast cell line LAD2 degranulation.

Neuroprotection against excitotoxicity by N-alkylglycines in rat hippocampal neurons

Excessive activation of glutamate receptors of the N-methyl-d-aspartate (NMDA) subtype is considered a relevant initial step underlying different neurodegenerative diseases. Recently, with the approval of memantine to treat Alzheimer dementia, NMDA receptors have regained clinical interest. Accordingly, the development and validation of NMDA receptor antagonists is being reconsidered. We recently identified a family of trialkylglycines that act as channel blockers of the NMDA receptor. Their neuroprotective activity against excitotoxic insults remains elusive. To address this issue, we first characterized the contribution of glutamate receptor sub-types to hippocampal death in culture as a function of days in culture in vitro (DIV). Whereas at 7 DIV neither NMDA nor glutamate produced a significant neuronal death, at 14 and 21 DIV, NMDA produced the death of 40% of the neurons exposed to this receptor agonist that was fully protected by MK-801. Similar results were obtained for l-glutamate at 14 DIV. In contrast, when neurons at 21 DIV were used, glutamate killed 51.1±4.9% of the neuronal population. This neuronal death was only partially prevented by MK-801, and fully abrogated by a combination of MK-801 and 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX). Glucose deprivation injured 37.1±9.2% of the neurons through a mechanism sensitive to MK-801. The family of recently identified N-alkylglycines tested protected neurons against NMDA and glucose-deprivation toxicity, but not against glutamate toxicity. Noteworthy, N-alkylglicines with a moderate protection against NMDA-induced toxicity strongly protected from β-amyloid toxicity. Collectively, these findings imply both NMDA and non-NMDA receptors in excitotoxicity of hippocampal neurons, and suggest that blockade of NMDA receptors alone may not suffice to efficiently abrogate neurodegeneration.

A novel inhaled Syk inhibitor blocks mast cell degranulation and early asthmatic response

Spleen tyrosine kinase (Syk) is essential for signal transduction of immunoreceptors. Inhibition of Syk abrogates mast cell degranulation and B cell responses. We hypothesized that Syk inhibition in the lung by inhaled route could block airway mast cells degranulation and the early asthmatic response without the need of systemic exposure. We discovered LAS189386, a novel Syk inhibitor with suitable properties for inhaled administration. The aim of this study was to characterize the in vitro and in vivo profile of LAS189386. The compound was profiled in Syk enzymatic assay, against a panel of selected kinases and in Syk-dependent cellular assays in mast cells and B cells. Pharmacokinetics and in vivo efficacy was assessed by intratracheal route. Airway resistance and mast cell degranulation after OVA challenge was evaluated in an ovalbumin-sensitized Brown Norway rat model. LAS189386 potently inhibits Syk enzymatic activity (IC50 7.2 nM), Syk phosphorylation (IC50 41 nM), LAD2 cells degranulation (IC50 56 nM), and B cell activation (IC50 22 nM). LAS189386 inhibits early asthmatic response and airway mast cell degranulation without affecting systemic mast cells. The present results support the hypothesis that topical inhibition of Syk in the lung, without systemic exposure, is sufficient to inhibit EAR in rats. Syk inhibition by inhaled route constitutes a promising therapeutic option for asthma.

An Inhibitor of Neuronal Exocytosis (DD04107) Displays Long-Lasting In Vivo Activity against Chronic Inflammatory and Neuropathic Pain

Small peptides patterned after the N terminus of the synaptosomal protein of 25 kDa, a member of the protein complex implicated in Ca2+-dependent neuronal exocytosis, inhibit in vitro the release of neuromodulators involved in pain signaling, suggesting an in vivo analgesic activity. Here, we report that compound DD04107 (palmitoyl-EEMQRR-NH2), a 6-mer palmitoylated peptide that blocks the inflammatory recruitment of ion channels to the plasma membrane of nociceptors and the release of calcitonin gene-related peptide from primary sensory neurons, displays potent and long-lasting in vivo antihyperalgesia and antiallodynia in chronic models of inflammatory and neuropathic pain, such as the complete Freunds adjuvant, osteosarcoma, chemotherapy, and diabetic neuropathic models. Subcutaneous administration of the peptide produced a dose-dependent antihyperalgesic and antiallodynic activity that lasted ≥24 h. The compound showed a systemic distribution, characterized by a bicompartmental pharmacokinetic profile. Safety pharmacology studies indicated that the peptide is largely devoid of side effects and substantiated that the in vivo activity is not caused by locomotor impairment. Therefore, DD04107 is a potent and long-lasting antinociceptive compound that displays a safe pharmacological profile. These findings support the notion that neuronal exocytosis of receptors and neuronal algogens pivotally contribute to chronic inflammatory and neuropathic pain and imply a central role of peptidergic nociceptor sensitization to the pathogenesis of pain.

Solid-phase synthesis of a library of amphipatic hydantoins. Discovery of new hits for TRPV1 blockade

Some heterocyclic systems, called privileged scaffolds, appear frequently in bioactive products and marketed drugs. The combination of a recognized privileged scaffold (hydantoin) and a functional group with high incidence in bioactive molecules (guanidine) guided the design of a library of amphipatic compounds, which allowed the discovery of novel TRPV1 ion channel blockers. The library was synthesized by parallel solid-phase synthesis from an orthogonally protected resin-bound Lys-Lys skeleton. Key steps of the synthetic procedure were the construction of the hydantoin ring, by reaction of the N-terminal amino group with N,N-disuccinimidyl carbonate (DSC) and subsequent base-induced cyclization, and the guanidinylation of the C-terminal Lys side-chain after removal of the Alloc protecting-group. The preliminary biological studies have allowed the identification of some of the key structural features directing the blockage of capsaicin-induced Ca(2+) influx through TRPV1 channels, particularly, the strong preference showed for highly lipophilic acyl groups and substituted guanidine moieties. Active compounds based on this new pharmacophoric scaffold that display in vitro and in vivo inhibitory activity.

Small molecules targeting the NMDA receptor complex as drugs for neuropathic pain.

Pain is a complex disease that usually remains poorly treated or undertreated, especially the neuropathic pain caused by injury to the peripheral or central nervous system. Antagonists of the NMDA receptor complex have emerged as potential drugs for pain management. A strong case is being raised for non-competitive or uncompetitive antagonists with low-to-moderate affinity and fast on/offset kinetics as drugs with good therapeutic profiles, because of their reduced side effects.

Characterization of a model of tracheal plasma extravasation in passively sensitized rats using anti-allergic and anti-inflammatory drugs by oral and intratracheal route

The aim of the following study was to characterize a passive systemic anaphylaxis rat model of dinitrophenyl (DNP)-induced plasma extravasation in the trachea to determine if the model is appropriate for the evaluation of new drugs targeting airway mast cells by oral and intratracheal (i.t.) route. To this purpose we have used fluticasone and a range of anti-allergic drugs including compounds either active on mast cell activation, such as cromoglycate and the Syk inhibitor R406, or active on mast cell mediators, such as cetirizine and montelukast. To further characterize the model, the effect of fluticasone, cromoglycate and R406 on rat tracheal mast cell degranulation was also assessed histologically. DNP-induced tracheal plasma extravasation was inhibited by cromoglycate (i.v. and i.t.) and R406 (p.o.), but not by fluticasone (i.t.), cetirizine or montelukast (p.o.). Cromoglycate and R406 also showed inhibition of tracheal mast cell degranulation, whereas fluticasone was inactive. These results suggest that the DNP-induced tracheal plasma extravasation model constitutes a useful animal model for the evaluation, by oral and i.t. route, of new anti-allergic drugs intended to target airway mast cells.