In vitro assessment of the potential for abuse via the intravenous route of oxycodone DETERx® microspheres.

OBJECTIVE: Abuse of prescription analgesics is a well-recognized problem, with nearly 2 million people aged 12 years or older initiating nonmedical use of pain relievers in 2012. The prevalence of opioid abuse via intravenous (IV) injection has led to the development of dosage forms designed to deter abuse using different inactive ingredients and formulation strategies. This study evaluated the IV abuse potential for a novel, microsphere-encapsulated abuse-deterrent formulation of oxycodone, Xtampza™ ER (referred to as "oxycodone DETERx"). METHODS: The extraction of oxycodone DETERx and two comparators, extended-release oxycodone (oxycodone ER) and immediate-release oxycodone (oxycodone IR), was evaluated in small volumes (5 and 10 mL) of water after manipulation of the dosage forms. The syringeability and injectability of these products were evaluated to determine the feasibility of using these products via IV injection. RESULTS: The extraction of oxycodone from oxycodone DETERx was nominal, with <12 percent extracted under any test condition. Oxycodone ER and oxycodone IR had as much as 83 and 98 percent oxycodone extracted, respectively. Injectability and syringeability analyses showed that injection of oxycodone DETERx microspheres in suspension is not feasible. In contrast, oxycodone ER and oxycodone IR suspensions were more easily drawn into and expelled from a syringe. Furthermore, injection of molten oxycodone DETERx microspheres was also shown to be ineffective. CONCLUSION: The chemical and physical properties of oxycodone DETERx provide barriers to manipulating the microspheres for the purpose of IV injection.

Evaluation of an Extended-Release, Abuse-Deterrent, Microsphere-in-Capsule Analgesic for the Management of Patients with Chronic Pain With Dysphagia (CPD).

BACKGROUND: Patients who have chronic pain with dysphagia (difficulty swallowing) (CPD) often have difficulty taking oral medication and, as such, alter their medications by crushing or chewing in an attempt to make it easier to swallow. Such manipulation of currently marketed, extended-release (ER) opioid analgesics can significantly alter the pharmacokinetic (PK) properties of the formulations, resulting in poor treatment outcome or serious adverse events. There is an unmet medical need for oral ER opioid formulations suitable for patients with CPD. OBJECTIVE: The primary objectives of this study were to conduct in vitro studies to evaluate alternate means of administration of a new, extended-release (ER), abuse-deterrent, microsphere-in-capsule formulation of oxycodone for patients with CPD. Specifically, these studies investigated the in vitro equivalence of drug release rates from Oxycodone DETERx® ER intact capsules (control condition) and administration via alternate modes-opening the capsule and sprinkling the microspheres onto soft foods or administration through enteral tubes. Secondary objectives were to compare alternate modes of administration of Oxycodone DETERx® to a commercially available ER-morphine product. METHODS: Soft food study: Oxycodone DETERx® microspheres were sprinkled onto and mixed with several soft foods (ie, applesauce, vanilla pudding, strawberry jam, yogurt, and vanilla ice cream); the effect of drug contact time (0, 30, and 60 minutes) on drug release was studied. Enteral tube study: Oxycodone DETERx® microspheres were administered through varying sizes of nasogastric (10 and 12 Fr.) tubes and a 16 Fr. gastrostomy tube using 5 different delivery vehicles (ie, water, liquid nutritional feeds [Jevity®, Ensure®], and milk [whole milk and 2% milk]). Drug release rate was characterized using a standard in vitro dissolution methodology; dissolution of intact Oxycodone DETERx® capsules served as the control for both the soft food and enteral tube studies. Oxycodone concentration was measured using a standardized high-performance liquid chromatography (HPLC) assay. Similarity factor (f2) analysis was used to compare similarity of the dissolution profiles of test and control conditions. RESULTS: The mean dissolution profile of Oxycodone DETERx® microspheres sprinkled onto and mixed with each of the soft foods were similar (f2 > 50) to that of the control. Study drug-food contact time did not impact dissolution profiles. The dissolution data obtained from Oxycodone DETERx® microspheres passed through enteral feeding tubes of varying sizes were similar (f2 > 50) to that of the control. Unlike a marketed morphine sulfate ER pellet formulation, Oxycodone DETERx® did not clog any of the studied enteral tubes. CONCLUSION: A new ER, abuse-deterrent, microsphere-in-capsule formulation of oxycodone can be administered by sprinkling onto soft food without affecting the drug release profile of the formulation. The formulation can also be administered directly via enteral tubes without affecting drug release and without clogging enteral tubes. Oxycodone DETERx® may offer physicians and patients with CPD an alternate treatment option, especially in those patients who have dysphagia or an aversion to swallowing monolithic tablet/capsule formulations and for whom analgesic patches or other opioid formulations are not a viable therapeutic option.

Impact of physical manipulation on in vitro and in vivo release profiles of oxycodone DETERx®: an extended-release, abuse-deterrent formulation.

OBJECTIVE: In vitro: To assess the effect of common crushing techniques on particle size reduction (PSR) and in vitro drug-release kinetics of oxycodone DETERx® (herein DETERx) and of a commercially available oxycodone extended-release (ER) tablet. In vivo: To evaluate the impact of the most effective manipulation method identified in the in vitro study and the effect of chewing on the pharmacokinetics (PK) of DETERx relative to oxycodone solution. DESIGN: In vitro: Mechanical manipulation of dosage forms using common household utensils. In vivo: Open-label, randomized, active-controlled, crossover PK study. SUBJECTS: In vivo: Forty-four healthy male and female volunteers. METHODS: In vitro: DETERx capsule contents and marketed comparator tablets were subjected to manipulation (crushing) using 10 different household utensils. Particle size and dissolution analysis were conducted. In vivo: Subjects were randomly assigned to receive DETERx 40-mg capsules intact, crushed, or chewed or oxycodone solution. Serial blood samples were drawn for PK assessment. RESULTS: In vitro: The utensils used to manipulate DETERx capsule contents were either ineffective in reducing the particle size or produced only a small change in the median particle size and dissolution rate relative to the marketed comparator. In vivo: DETERx intact capsules provided significantly lower Cmax and longer Tmax values than oxycodone solution. Manipulation of DETERx by crushing (using the most effective method established in vitro) or chewing resulted in bioequivalent plasma concentration-time profiles to the intact dosage form. CONCLUSION: These mechanical manipulation and PK studies demonstrated that DETERx beads retained their ER properties after mechanical tampering and chewing by study subjects.

Comparative reactivity of the myeloperoxidase-derived oxidants hypochlorous acid and hypothiocyanous acid with human coronary artery endothelial cells.

In the immune response, hypohalous acids are generated by activated leukocytes via the release of myeloperoxidase and the formation of H2O2. Although these oxidants have important bactericidal properties, they have also been implicated in causing tissue damage in inflammatory diseases, including atherosclerosis. Hypochlorous acid (HOCl) and hypothiocyanous acid (HOSCN) are the major oxidants formed by myeloperoxidase under physiological conditions, with the ratio of these oxidants dependent on diet and smoking status. HOCl is highly reactive and causes marked cellular damage, but few data are available on the effects of HOSCN on mammalian cells. In this study, we have compared the actions of HOCl and HOSCN on human coronary artery endothelial cells (HCAEC). HOCl reacts rapidly with the cells, resulting in extensive cell death by both apoptosis and necrosis, with necrosis dominating at higher oxidant doses. In contrast, HOSCN is consumed more slowly, with cell death occurring only by apoptosis. Exposure of HCAEC to HOCl and HOSCN induces changes in mitochondrial membrane permeability, which, in the case of HOSCN, is associated with mitochondrial release of proapoptotic factors, including cytochrome c, apoptosis-inducing factor, and endonuclease G. With each oxidant, apoptosis appears to be caspase-independent, with the inactivation of caspases 3/7 observed, and pretreatment of the cells with the caspase inhibitor Z-VAD-fmk having no effect on the extent of cell death. Loss of cellular thiols, depletion of glutathione, and the inactivation of thiol-dependent enzymes, including glyceraldehyde-3-phosphate dehydrogenase, were seen with both oxidants, though to a much greater extent with HOCl. The ability of myeloperoxidase-derived oxidants to induce endothelial cell apoptosis may contribute to the formation of unstable lesions in atherosclerosis. The results with HOSCN may be particularly significant for smokers, who have elevated plasma levels of SCN(-), the precursor of this oxidant.

Influenza A virus infection impairs mycobacteria-specific T cell responses and mycobacterial clearance in the lung during pulmonary coinfection.

Individuals infected with mycobacteria are likely to experience episodes of concurrent infections with unrelated respiratory pathogens, including the seasonal or pandemic circulating influenza A virus strains. We analyzed the impact of influenza A virus and mycobacterial respiratory coinfection on the development of CD8 T cell responses to each pathogen. Coinfected mice exhibited reduced frequency and numbers of CD8 T cells specific to Mycobacterium bovis bacille Calmette-Guérin (BCG) in the lungs, and the IFN-γ CD8 T cell response to BCG-encoded OVA was decreased in the lungs of coinfected mice, when compared with mice infected with BCG alone. Moreover, after 2 wk of infection, mice coinfected with both pathogens showed a significant increase in the number of mycobacteria present in the lung compared with mice infected with BCG only. Following adoptive transfer into coinfected mice, transgenic CD8 T cells specific for OVA(257-264) failed to proliferate as extensively in the mediastinal lymph nodes as in mice infected only with BCG-OVA. Also noted was a reduction in the proliferation of BCG-specific CD4 transgenic T cells in mice coinfected with influenza compared with mice infected with BCG alone. Furthermore, phenotypic analysis of CD11c(+) dendritic cells from mediastinal lymph nodes of the infected mice showed that coinfection was associated with decreased surface expression of MHC class II and class I. Thus, concurrent pulmonary infection with influenza A virus is associated with decreased MHC expression on dendritic cells, reduced activation of BCG-specific CD4 and CD8 T cells, and impaired clearance of mycobacteria.