Effective nose-to-brain drug delivery using a combination system targeting the olfactory region in monkeys.

The nose-to-brain (N2B) pathway has garnered attention because it transports drugs directly into the brain. Although recent studies have suggested the necessity of selective drug administration to the olfactory region for effective N2B drug delivery, the importance of delivering the formulation to the olfactory region and the detailed pathway involved in drug uptake in primates brain remain unclear. Here, we developed a combination system for N2B drug delivery comprising a proprietary mucoadhesive powder formulation and a dedicated nasal device (N2B-system) and evaluated it for nasal drug delivery to the brain in cynomolgus monkeys. This N2B-system demonstrated a much greater formulation distribution ratio in the olfactory region in an in vitro experiment using a 3D-printed nasal cast and in vivo experiment using cynomolgus monkeys, as compared to that in other nasal drug delivery systems that comprise of a proprietary nasal powder device developed for nasal absorption and vaccination and a commercially available liquid spray. Additionally, Texas Red-labeled dextran (TR-DEX, 3 kDa) was administered using the N2B-system to estimate the drug transition pathway from the nasal cavity to the brain. TR-DEX preferentially localized to the olfactory epithelium and reached the olfactory bulb through the cribriform foramina. Moreover, domperidone, a model drug with poor blood-brain barrier permeability, was administered to assess the brain uptake of medicine after olfactory region-selective administration by using the N2B-system. Domperidone accumulation in the brain was evaluated using positron emission tomography with intravenously administered [18F]fallypride based on competitive inhibition of the dopamine D2 receptor (D2R). Compared to other systems, the N2B-system significantly increased D2R occupancy and domperidone uptake in the D2R-expressing brain regions. The current study reveals that the olfactory region of the nasal cavity is a suitable target for efficient nasal drug delivery to the brain in cynomolgus monkeys. Thus, the N2B-system, which targets the olfactory region, provides an efficient approach for developing effective technology for nasal drug delivery to the brain in humans.

Indirect SPECT Imaging Evaluation for Possible Nose-to-Brain Drug Delivery Using a Compound with Poor Blood-Brain Barrier Permeability in Mice.

Single-photon emission computed tomography (SPECT) imaging using intravenous radioactive ligand administration to indirectly evaluate the time-dependent effect of intranasal drugs with poor blood-brain barrier permeability on brain drug distributions in mice was evaluated. The biodistribution was examined using domperidone, a dopamine D2 receptor ligand, as the model drug, with intranasal administration at 0, 15, or 30 min before intravenous [123I]IBZM administration. In the striatum, [123I]IBZM accumulation was significantly lower after intranasal (IN) domperidone administration than in controls 15 min after intravenous [125I]IBZM administration. [123I]IBZM SPECT was acquired with intravenous (IV) or IN domperidone administration 15 min before [123I]IBZM, and time-activity curves were obtained. In the striatum, [123I]IBZM accumulation was clearly lower in the IN group than in the control and IV groups. Time-activity curves showed no significant difference between the control and IV groups in the striatum, and values were significantly lowest during the first 10 min in the IN group. In the IN group, binding potential and % of receptor occupancy were significantly lower and higher, respectively, compared to the control and IV groups. Thus, brain-migrated domperidone inhibited D2R binding of [123I]IBZM. SPECT imaging is suitable for research to indirectly explore nose-to-brain drug delivery and locus-specific biological distribution.

Evaluation of Systemic and Mucosal Immune Responses Induced by a Nasal Powder Delivery System in Conjunction with an OVA Antigen in Cynomolgus Monkeys.

An immune response for a nasal ovalbumin (OVA) powder formulation with an applied nasal delivery platform technology, consisting of a powdery nasal carrier and a device, was evaluated in monkeys with similar upper respiratory tracts and immune systems to those of humans, in order to assess the applicability to a vaccine antigen. Nasal distribution and retention studies using a 3D nasal cavity model and manganese-enhanced MRI were conducted by administering nasal dye and manganese powder formulations with the applied technology. Systemic and mucosal immune responses for the nasal OVA powder formulation were evaluated by determining serum IgG and nasal wash IgA antibody titers. The nasal dye and manganese powder formulations showed wider distribution and longer retention time than did a nasal liquid formulation. The nasal OVA powder formulation also showed comparable and higher antigen-specific IgG antibody titer to an injection and nasal liquid formulation, respectively. Furthermore, antigen-specific IgA antibody response was detected only for the nasal OVA powder formulation. The present study suggests that the technology, originally designed for drug absorption, is promising for nasal vaccines, enabling both a mucosal immunity response as the first line of defense and systemic immunity response as a second line of defense against infection.

Rapid Absorption of Dry-Powder Intranasal Oxytocin.

PURPOSE: To probe the suitability of a dry-powder oxytocin formulation containing a carrier (µco™; SNBL, Ltd.) for intranasal (IN) administration to treat post-partum hemorrhage in the developing world. Specifically, to investigate (1) whether IN administration can achieve rapid systemic absorption in cynomolgus monkeys, and (2) whether the formulation exhibits sufficient physical and chemical stability. This study was conducted to support Merck for Mothers, Merck's 10-year global initiative to end preventable maternal deaths. METHODS: A partial-crossover pharmacokinetic (PK) study in cynomolgus monkeys (n = 6) was utilized to compare in vivo absorption of dry-powder IN oxytocin at three dose levels against an IM injection of an aqueous oxytocin formulation. Particle size distribution, delivered dose and chemical assay were monitored over a 12 month stability study. RESULTS: IN administration of oxytocin resulted in short (5 min) Tmax and good dose linearity in AUC and Cmax over the dose range tested (10-80 IU per animal). The relative bioavailability (BA) of IN oxytocin to IM injection was approximately 12%. The 80 IU formulation exhibited good physical stability and consistent dosing. After 12 months at 30°C/65%RH, pouched samples retained 86.0% of their original assay value. CONCLUSIONS: The PK and stability data suggests that IN administration of oxytocin formulated in the µco™ carrier may represent a viable option for rapid systemic absorption in humans and a product compatible with resource-scarce regions.

An effective absorption behavior of insulin for diabetic treatment following intranasal delivery using porous spherical calcium carbonate in monkeys and healthy human volunteers.

Porous spherical calcium carbonate (PS-CaCO(3)), in contrast to regular calcium carbonate (CaCO(3)), which has a cuboidal particle shape, has a characteristic spherical particle shape with a large number of porous, sliver crystals. The effect of PS-CaCO(3) as a drug carrier on intranasal insulin absorption was investigated in cynomolgus monkeys and healthy human volunteers. Each insulin formulation (powder) containing PS-CaCO(3) or regular CaCO(3) was administered intranasally. Serum insulin and glucose levels after administration were evaluated. The insulin absorption after intranasal administration with each CaCO(3) was found to be much more rapid than that after subcutaneous administration. The serum insulin level after intranasal insulin delivery (16 U per monkey) with PS-CaCO(3) showed a higher C(max) (403.5 microU/mL) and shorter T(max) (0.167 h) when compared with regular CaCO(3). The serum glucose level reduction rate after intranasal delivery using PS-CaCO(3) was faster than that of regular CaCO(3), reflecting the difference in absorption rates. Following repeated intranasal administrations for 4 weeks in monkeys, no toxicity was observed even with a maximum insulin dose level of 25 U. Furthermore, the intranasal insulin absorption rate with PS-CaCO(3) in healthy humans was also observed to be considerably faster than that with regular CaCO(3). Effects of PS-CaCO(3) on a more effective absorption behavior of insulin were considered to be the result of a greater affinity between the nasal mucosa layer and PS-CaCO(3), which is closely related to its structural characteristics. Thus, intranasal insulin delivery using PS-CaCO(3) is thought to be a safe and highly available system enabling more effective insulin absorption behavior with the appearance of endogenous postprandial insulin secretion in healthy humans. We believe that our intranasal insulin delivery system enabling a rapid and short-acting pharmacological effect against postprandial hyperglycemia will be more beneficial than pulmonary insulin delivery systems in the treatment of diabetes.

Analysis and prediction of absorption behavior of colon-targeted prodrug in rats by GI-transit-absorption model.

The gastrointestinal-transit-absorption (GITA) model is useful for the analysis and the prediction of the absorption behavior of drugs orally administered as solutions. In the present study, we tried to predict the plasma concentration-time profile of a colon-targeted prodrug, salicylazosulfanilic acid (SASA), and its parent drug, 5-aminosalicylic acid (5-ASA) which is regenerated after dosing. Prediction of plasma concentration-time profiles for SASA and 5-ASA was performed based on the GITA model using parameters describing GI-transit kinetics, the absorption in each GI segment, and the regeneration of 5-ASA in cecum. Plasma concentration-time profiles of both SASA and 5-ASA after oral administration of SASA were predicted very well by introducing a factor for the first-pass elimination of 5-ASA into the GITA model. The simulation study using the parameters obtained in the present study showed that about 94.7% of SASA reaches the cecum, where 5-ASA is regenerated very rapidly and 76.0% of 5-ASA is absorbed. Furthermore, the bioavailability of 5-ASA was estimated to be 0.330 because of the first-pass elimination through both cecum and liver. In conclusion, the absorption behaviors of a prodrug and its regenerated parent drug can be predicted very well and be clarified successfully using the GITA model.

Prediction of plasma concentration-time curve of orally administered theophylline based on a scintigraphic monitoring of gastrointestinal transit in human volunteers.

The plasma concentration-time profile of theophylline after oral administration in human volunteers was predicted using the individual gastrointestinal (GI) transit data monitored by a gamma scintigraphic technique. Theophylline was administered as aminophylline under fasted and fed condition, along with 99mTc-labeled diethylenetriamine-pentaacetic acid (DTPA), an unabsorbable marker to evaluate the GI transit by a gamma scintigraphic technique. Two healthy male volunteers participated under fasted and fed conditions in a crossover study. The GI transit was evaluated by dividing the GI tract to four segments, stomach, jejunum, ileum and cecum/colon. Under the fed condition, the GI transit pattern for each segment was confirmed to alter considerably, causing a delay in the gastric emptying mainly. Further, the plasma concentration curves of theophylline after oral administration were predicted using the GI-Transit-Absorption Model on the basis of individual GI transit parameters calculated by the fitting of the observed data to the GI-Transit Kinetic Model. The absorption rate constant in each segment and the pharmacokinetic parameters after intravenous administration used for the prediction were the values extrapolated from the data in rats and the ones normalized from the values in literatures, respectively. The plasma concentration-time curves for theophylline were well predicted using obtained individual GI transit parameters. The analysis using this method could estimate the variable absorption behavior governed by the GI transit in detail.