Changes in facial temperature measured by digital infrared thermal imaging in patients after transnasal sphenopalatine ganglion block: Retrospective observational study.

Sphenopalatine ganglion block (SPGB) is a technique developed in the 1990s for the management of head and neck pain patients. Recently, transnasal sphenopalatine ganglion block (TN-SPGB) has been widely used for these patients; however, no objective methods exist for validating the success of TN-SPGB. In this study, we measured the changes in facial temperature before and 30 minutes after TN-SPGB by using digital infrared thermal imaging (DITI) to validate its success.The medical records of patients, who underwent TN-SPGB and facial DITI between January 2016 and December 2017, were reviewed. TN-SPGB and facial DITI were performed 36 times in 32 patients. The changes in facial temperatures measured at the forehead (V1), maxillary area (V2), and mandibular area (V3) by using DITI before and 30 minutes after TN-SPGB were recorded and compared. The temperatures on the ipsilateral and contralateral sides of these areas were also compared. The comparison between pain relief group and pain maintenance group was analyzed.After TN-SPGB, the temperature decreased significantly on both sides of V1 (P = .0208, 0.0181). No significant differences were observed between the ipsilateral and contralateral sides (P > .05). There was no correlation between changes in temperature and changes in pain score in the pain regions after the procedure (P > .05).The temperature decreased significantly in V1 area at 30 minutes after TN-SPGB compared with the temperature before TN-SPGB. Based on these results, we propose using DITI to measure temperature changes as an objective method for verifying the success of TN-SPGB.

A mixed polymeric micellar formulation of itraconazole: Characteristics, toxicity and pharmacokinetics.

A mixed polymeric micelle formulation of itraconazole (ITZ-PM) was prepared using monomethoxy poly(ethylene glycol)-b-poly(lactic acid) and poly(lactic acid) as drug carrier materials. The ITZ-PM formulation remarkably increased the itraconazole solubility up to 15 mg/mL in aqueous media and provided stable solutions at a wide range of concentrations and pH's. In toxicity studies of single and 28-day repeated administrations to rats and dogs, ITZ-PM was well tolerated at dose levels corresponding to clinical doses. The pharmacokinetic profiles of ITZ-PM for itraconazole and its major metabolite, hydroxy-itraconazole, were comparable to those of the cyclodextrin formulations (Sporanox(R) Injection and Oral Solution) in rats and dogs. These results suggest that ITZ-PM can be an advantageous formulation for both intravenous and oral routes.

Development of docetaxel-loaded intravenous formulation, Nanoxel-PM™ using polymer-based delivery system.

Nanoxel-PM™, docetaxel-loaded methoxy-poly(ethylene glycol)-block-poly(d,l-lactide) (mPEG-PDLLA) micellar formulation was prepared in an effort to develop alternative, less toxic and efficacious Tween 80-free docetaxel formulation, and its pharmacokinetics, efficacy, and toxicity were evaluated in comparison with Taxotere® in preclinical studies. The mean diameter of the Nanoxel-PM™ was 10-50 nm and the polydispersity of samples exhibited a narrow size distribution and monodisperse unimodal pattern. Pharmacokinetic study in mice, rats and beagle dogs revealed that Nanoxel-PM™ exhibited similar pharmacokinetic profiles (C(max), AUC, t(1/2), CL, V(ss)) to Taxotere, and the relative mean AUC(t) and C(max) of Nanoxel-PM™ to Taxotere® were within 80-120%. Furthermore, excretion study in rats demonstrated that there was no statistically significant difference in the amount excreted in feces or urine as an unmetabolized docetaxel between Nanoxel-PM™ and Taxotere®. Its pharmacokinetic bioequivalence resulted in comparable anti-tumor efficacy to Taxotere® in human lung cancer xenografts H-460 in nude mice as well as in lung, ovary and breast cancer cell lines. Several animal toxicity studies on Nanoxel-PM™ compared with Taxotere® were carried out. In single dose rat and dog model and repeated dose mouse model, both Nanoxel-PM™ and Taxotere® exhibited similar toxic effects on hematology and body weight gain. On the other hand, vehicle related hypersensitivity reactions and fluid retentions were not observed when Nanoxel-PM™ was administered, unlike Taxotere®, in the beagle dog study. Based on these results, it is expected that Nanoxel-PM™ can reduce side effects of hypersensitivity reactions and fluid retention while retaining antitumor efficacy in cancer patients. Currently, Nanoxel-PM™ is under evaluation for bioequivalence with Taxotere® in a multi-center, open-label, randomized, crossover study.

Ionically fixed polymeric nanoparticles as a novel drug carrier.

PURPOSE: In this study, we have prepared a novel polymeric drug delivery system comprised of ionically fixed polymeric nanoparticles (IFPN) and investigated their potential as a drug carrier for the passive targeting of water-insoluble anticancer drugs. MATERIALS AND METHODS: For this purpose, the physicochemical characteristics of the IFPN were investigated by comparing them with conventional polymeric micelles. IFPN containing paclitaxel were prepared and evaluated for in vitro stability and in vivo pharmacokinetics. RESULTS: The IFPN were successfully fabricated using a monomethoxypolyethylene glycol-polylactide (mPEG-PLA) diblock copolymer and a sodium salt of D,L-poly(lactic acid) (D,L-PLACOONa) upon the addition of CaCl2. The transmittance of the IFPN solution was much lower than that of a polymeric micelle solution at the same polymer concentration implicating an increase in the number of appreciable particles. The particle size of the IFPN was approximately 20 approximately 30 nm which is in the range of particle sizes that facilitate sterile filtration using a membrane filter. The IFPN also have a regular spherical shape with a narrow size distribution. The zeta potential of the IFPN was almost neutral, similar to that of the polymeric micelles. In contrast, mixed micelles with a combination of mPEG-PLA and D,L-PLACOONa prior to the addition of Ca2+ showed a negative charge (-17 mV), possibly due to the carboxyl anion of polylactic acid exposed on the surface of the micelles. The IFPN formulation was highly kinetically stable in aqueous medium compared to the polymeric micelle formulation. The molecular weight of D,L-PLACOONa in the IFPN and the mPEG-PLA/D,L-PLACOONa molar ratio had a great influence upon the kinetic stability of the IFPN. Pharmacokinetic studies showed that the area under the concentration vs time curve (AUC) of IFPN in blood was statistically higher (about two times) when compared with that of Cremophor EL-based formulation (Taxol equivalent) or polymeric micelle formulation. CONCLUSIONS: The results suggests that the IFPN were retained in the circulation long enough to play a significant role as a drug carrier in the bloodstream, possibly resulting in improved therapeutic efficiency. Therefore, the IFPN are expected to be a promising novel polymeric nanoparticulate system for passive tumor targeting of water-insoluble anticancer drugs including paclitaxel.