Effect of Equipment Parameters on Amount and Dispersion of Wetting Liquid in Planetary Centrifugal Granulation.

In planetary centrifugal wet granulation, the binder is often mixed into the formulation as a powder, followed by the addition of a wetting liquid, in a single step. Therefore, the amount and dispersion of the wetting liquid are important factors that determining granulation success and granules characteristics. In this study, granulation experiments, according to the Box-Behnken design, were performed. Further, the effects of equipment parameters, namely, processing speed, processing time, and vessel size, on the minimum amount of wetting liquid required to enable granulation and dispersion state in the vessel were statistically analyzed. Placebo granules were formulated with lactose hydrate and corn starch (7 : 3), using sodium carmellose as a binder. Results showed that the amount of wetting liquid decreased with increase in processing speed, processing time, and vessel size; however, the dispersion state of the wetting liquid was not significantly affected. Analysis of the effects of the equipment parameters on granule characteristics showed that a larger vessel size was proportional to a larger median diameter and smaller particle-size distribution width (span), and a faster processing speed was proportional to a smaller span. Furthermore, granules with the target properties could be prepared according to the parameters estimated from the model. In conclusion, the equipment parameters for controlling the amount of wetting liquid, which affected the granule properties, were clarified.

Comparative analysis of intercellular lipid organization and composition between psoriatic and healthy stratum corneum.

The lipid composition and organization of the stratum corneum (SC) in patients with psoriasis and healthy subjects were compared using X-ray diffraction, Fourier-transform infrared spectroscopy (FT-IR), and ultraperformance liquid chromatography, combined with time-of-flight mass spectrometry (UPLC-TOFMS). In healthy SC (HSC), SC lipids formed two lamellar phases (long and short periodicity phases). Hexagonal and orthorhombic hydrocarbon-chain packing were observed in the lateral lipid organization at 30 °C via X-ray diffraction. In HSC, the lamellar phases and the hydrocarbon-chain packing organizations changed with elevated temperatures and finally disappeared. In these behaviors, the high-temperature hexagonal hydrocarbon-chain packing organization, which appeared above the orthorhombic hydrocarbon-chain packing organization, transformed to the liquid phase at about 90 °C in HSC. In psoriatic SC (PSC), hexagonal hydrocarbon-chain packing organization disappeared at about 65 °C with elevated temperatures. No high-temperature hexagonal hydrocarbon-chain packing organization were observed in PSC during heating process. Disorder of the hydrocarbon-chain packing of SC lipids was observed in PSC via FT-IR. In UPLC-TOFMS, free fatty acid (FFA) and ceramide (CER) compositions differed between patients with PSC and HSC. Specifically, the levels of ultra-long chain fatty acids containing CER and phytosphingosine-containing CER were decreased, while those of sphingosine and dihydrosphingosine-containing CER and unsaturated FFA were increased in PSC. Furthermore, FFA and CER carbon chain lengths decreased in patients with PSC. These results suggest that the alteration of SC lipid composition and the reduction of carbon chain lengths in PSC lowered the structural transformation temperature, thereby reducing barrier function.

Extemporaneous preparation of rifampicin granules from capsules to improve usability.

OBJECTIVES: Manipulation of tablets or capsules is frequently carried out in pharmacies to regulate doses for personalised therapy. We proposed the use of reconstructed granules as a suitable, flexible dosage form and developed an on-site granulation method using a compounding mixer. The aim of this study was to demonstrate the feasibility of small-scale preparation of granules in a pharmacy setting. Rifampicin capsules were used as a model medicine because of the associated need for drug desensitisation therapy. METHODS: The contents of a rifampicin capsule were granulated using a compounding mixer, and small ointment containers (12 mL) with filling rates of 4%, 8%, 12%, and 16% were used as granulation vessels. The obtained granules were examined for particle size distribution, yield, crystal transition, drug dissolution profile, storage stability, and weight loss during dosing. RESULTS: The yields increased by >95%, and the span of the particle size distribution decreased to 1.0, as the filling rate increased. The smallest batch size was found to be 0.8 g in a 12 mL vessel. Examination of the resultant granules revealed that granulation did not affect the crystal polymorphism, dissolution profile, or storage stability of rifampicin. Furthermore, the weight loss of the granules during the dosing process was significantly lower than that of the capsule powder content. CONCLUSIONS: We demonstrated that granules with sufficient quality for clinical use could be extemporaneously prepared using a compounding mixer in pharmacies. This improved the usability of the medicine, preventing weight loss, and making it a suitable alternative formulation for precise personalised pharmacotherapy.

Stratum Corneum Function: A Structural Study with Dynamic Synchrotron X-ray Diffraction Experiments.

Studies on the effectiveness of substances such as drugs and cosmetics that act on the skin require structural evidence at the molecular level in the stratum corneum to clarify their interaction with intercellular lipid and soft keratin. For this purpose, when applying the substances to the stratum corneum X-ray diffraction experiment is one of the powerful tools. To detect minute structural changes in a stratum corneum sample, using a "solution cell", dynamic synchrotron X-ray diffraction measurements were performed when applying aqueous solution of the substances to the stratum corneum: (1) It was found that a surfactant, sodium dodecyl sulfate, significantly disrupted the long-period lamellar structure. (2) To study the effects of water, structural modifications of the short-period lamellar structure and the soft keratin in corneocytes were measured as a function of time. At the initial water content of 15 wt%, the spacings of the short-period lamellar structure and the soft keratin increased toward those at the water content of 25 wt%, that is a key water content in the stratum corneum. (3) Nanoparticles composed of assembly of amphiphilic molecules are one of the leading pharmaceutical formulations. When the nanoparticles were applied, a new assembly of amphiphilic molecules originated from the nanoparticle appeared. This phenomenon suggests that the formation of the new assembly at the surface of skin is concerned with the release of the drug from the nanoparticles. (4) When ethanol was applied to the stratum corneum, only the liquid state in the intercellular lipid matrix was dissolved. After the removal of ethanol from this stratum corneum, the ordered hydrocarbon-chain packing structures appeared. From this fact we would propose that the liquid state region is the main pathway for hydrophobic drugs with a small molecular weight in connection with the so-called 500 Da rule. Here, not only the technique but also the background to these studies and the characteristic results obtained from these studies are explained.

Development of novel polyglycerol fatty acid ester-based nanoparticles for the dermal delivery of tocopherol acetate.

The aim of this study was to develop and evaluate novel polyglycerol fatty acid ester (PGFE)-based nanoparticles (NPs) for the dermal delivery of tocopherol acetate (TA). TA-loaded PGFE-based NPs (PGFE-NPs) were prepared by mixing PGFE, soya phosphatidylcholine, dimyristoylphosphatidylglycerol, and TA with film using the film rehydration and extrusion method. The prepared formulations were analyzed by dynamic light scattering, small-angle X-ray diffraction and polarization microscopy. An in vitro skin accumulation test was performed with TA under occlusive and non-occlusive applications, using Yucatan micropig skin. The size range of the TA-loaded liposome and PGFE-NPs was 107-128 nm, and they were encapsulated in 1.6-2.3 mg/mL TA. All PGFE-NP formulations were negatively charged and stable for 2 weeks. Under occlusive applications, all formulations induced small amounts of TA accumulation in the epidermis but not in the dermis. However, under non-occlusive applications, some of PGFE-NP formulations enhanced TA accumulation in the epidermis. Furthermore, only the polyglycerol 4-laurate (PG4L)-based formulation induced dermal TA accumulation with the change in the formulation from a vesicular to bilayer stacked structure following water evaporation under non-occlusive applications. These results indicated that the novel TA-loaded PG4L formulation enabled the dermal delivery of TA in non-occlusive applications.

Evaluation of Dantrolene Granules Extemporaneously Reformulated from Capsules in a Pharmacy.

Dantrolene capsule, an effective therapeutic agent for the treatment of spasticity, is administered to children who cannot swallow the capsule after reformulation into a powder. The powdered drug can alter the specified dosage and it is also difficult to dispense the powdered formulation because of its bulky and sticky nature. To resolve these problems, we reformulated dantrolene capsules into granules using a centrifugal planetary mixer in the pharmacy. The granules containing lactose-cornstarch, D-mannitol, or microcrystalline cellulose as a diluent were examined to determine particle size distribution, flowability, drug content uniformity, and disintegration time. The granules with microcrystalline cellulose were superior to the other forms, owing to their smaller size, good drug content uniformity, and rapid disintegration. We further investigated the usability of the granules in the dispensing procedure (dividing and packing) and in the dosing process (retrieval from package) using the powders as controls. The deviation of the divided amount and loss on dosing were reduced relative to the powders. In addition, drug dissolution properties and storage stability for 12 months were the same as those of the powders. Therefore, we concluded that dantrolene granules are excellent alternatives as an extemporaneous preparation in pharmacies.

Association of dry skin with intercellular lipid composition of stratum corneum after erlotinib administration.

PURPOSE: Erlotinib, an inhibitor of the epidermal growth factor receptor tyrosine kinase, causes skin disorders such as dry skin, which impairs the skin barrier function. Stratum corneum (SC) lipids play an important role in skin barrier function; therefore, this study aimed to investigate the relationship between erlotinib-related dry skin and changes in the intercellular lipid composition and structure of the SC. METHODS: Overall, 21 patients with non-small lung cancer were enrolled in this study. All patients received 150 mg/day erlotinib orally. A SC sample of each patient was collected from the inner forearm using the tape stripping method on days 0, 7, 14, 28, and 56 after erlotinib administration. The intercellular lipid components of ceramide (CER), free fatty acid (FFA), and cholesterol sulfate (CS) in samples extracted from the tape were analyzed using liquid chromatography/time-of-flight/mass spectrometry. SC samples from six healthy subjects were collected as controls on days 0, 28 and 56 and analyzed similarly. RESULTS: Although total CER and FFA levels were not changed after erlotinib administration, the levels of CER subclasses [AP] and [AH] and hydroxy FFA, which are structural components of CER subclass [A], decreased. In contrast, the CS levels increased after erlotinib administration. Moreover, higher CS levels in the SC correlated with the clinical condition of dry skin. No changes were observed in the SC lipid composition in healthy subjects. CONCLUSION: Erlotinib-related dry skin was associated with a higher CS level in the SC.

Small-Scale Spherical Granulation Using a Planetary Centrifugal Mixer.

A concise spherical granulation method is required to prepare extemporaneously granules remanufactured from oral dosage forms for administration to individuals who cannot swallow tablets or capsules. In this study, we determined the feasibility of spherical granulation using a planetary centrifugal mixer. A model formulation, 20% ibuprofen (IBP) granules, was prepared using a lactose/cornstarch (7 : 3, w/w) mixture or D-mannitol as diluents, and changes in granule characteristics (mean diameter (d50), distribution range of granule size (span), and yield) were evaluated according to the amount of water added and the granulation time. The amount of water was assessed using the plastic limit value as measured using a digital force gauge. We successfully produced granules, and larger amounts of water and longer granulation times resulted in larger d50 values and smaller span values. The optimal granulation time was 45 s and the optimal water contents were 70 and 67.5% of the plastic limit value for the lactose/cornstarch mixture and D-mannitol, respectively. When compared to commercial 20% IBP granules, powder X-ray diffraction and differential scanning calorimetry analyses showed that the granulation process did not alter the crystallinity of the drug. Thus, this novel granulation method using a planetary centrifugal mixer may be a promising technique for compounding in pharmacies and in pharmaceutical manufacturing.

[Development of a Breathable Protective Ointment for Moisture-associated Skin Damage].

In this symposium, we present a novel breathable protective ointment (BPO) formulation developed at the University of Shizuoka for the prevention of moisture-associated skin damage (MASD) intended for use in healthcare settings. MASD occurs when moisture is in constant contact with the skin for prolonged periods of time, causing degradation of the skin barrier. Exposure to physical or chemical stimuli in addition to moisture may lead to different types of moisture-associated dermatitis such as incontinence-associated or periwound dermatitis. Another type of moisture-associated dermatitis, diaper dermatitis, is treated with protective ointments such as white petrolatum and zinc ointment. These ointments protect the skin from irritants but also block insensible dermal perspiration, which promotes further skin maceration. Therefore, we have developed a BPO formulation from white petrolatum and calcium carbonate, which serve as a protectant and pore-forming agent, respectively. In vitro water-proof tests confirmed the skin-protective properties of the BPO, and moisture-permeation tests indicated its breathability. Moreover, the BPO protected the skin from irritants without the loss of skin hydration in rats. Our next step involves the trial of BPO in infants with diaper dermatitis. In the future, this BPO could be used as an ointment base for active pharmaceutical ingredients used to prevent MASD.

Development of a Novel Simple Gel Formulation Containing an Ion-Pair Complex of Diclofenac and Phenylephrine.

BACKGROUND AND AIM: Since the pharmacological effects of diclofenac (DF) are short-lived because of its short half-life, prolongation of the pharmacological effect in a topical formulation is needed for more appropriate clinical use. For the enhancement of dermal accumulation and prolongation of the pharmacological effect of drugs, the aim of this study was to develop a simple gel formulation containing an ion-pair complex of DF and phenylephrine (PHE), which induce constriction of the vascular smooth muscles. MATERIALS AND METHODS: The ion-pair complex was prepared by mixing sodium DF and an ethanolic solution of PHE. The formed complex was characterized by powder X-ray diffraction (PXRD) and Fourier-transform infrared (FT-IR) spectroscopy. The ion-pair complex for the gel formulation was prepared by mixing an equimolar concentration of 50% 1,3-butylene glycol and distilled aqueous solution of 2% xanthan gum, which was characterized by proton nuclear magnetic resonance (1H-NMR). Skin permeation and accumulation of DF and PHE were evaluated by in vitro and in vivo studies. RESULTS: From the results of PXRD and FT-IR, it was suggested that new crystalline peaks formed by the ion-pair complex and their complex interacted with the carboxyl group in DF and the amino group in PHE. In the gel formulation, the ion-pair complexes were detected by 1H-NMR. The ion-pair complex enhanced the accumulation of DF in the skin in the in vitro study. On the other hand, PHE accumulation in the dermis increased with the ion-pair complex, as exhibited by the in vivo study. CONCLUSION: A new gel formulation containing the ion-pair complex of DF and PHE was developed, which improved the accumulation of DF in skin.

Study on the drug permeation mechanism from flurbiprofen-loaded glyceryl monooleyl ether-based lyotropic liquid crystalline nanoparticles across the skin: Synchrotron X-ray diffraction and confocal laser scanning microscopy study.

The mechanism underlying the skin permeation of flurbiprofen (FLU)-loaded, glyceryl monooleyl ether-based liquid crystalline nanoparticles (LCNs) with a hexagonal structure was examined by synchrotron X-ray diffraction and confocal laser scanning microscopy (CLSM). Fluorescent-labeled, FLU-loaded LCNs were prepared using coumarin 6 and rhodamine B 1,2-dihexadecanoyl-sn-glycero-3-phosphoethanolamine, triethylammonium salt (Rh-PE), which produce green and red fluorescence, respectively. Application of FLU-loaded LCNs to the hairless mouse stratum corneum (SC) induced expansion of the lattice spacing of the hexagonal structure with FLU release, as confirmed by the changes in the small-angle X-ray diffraction profiles. In addition, the FLU-loaded LCNs completely released FLU near the surface of the SC, which then penetrated the SC. Consequently, the repeat distance of the long periodicity phase was slightly modified. CLSM revealed green fluorescence in the epidermis and hair follicles and red fluorescence in the SC. In conclusion, LCNs adopt several permeation pathways: one is partly via the intercellular matrix and the other is the epidermis via hair follicles.

Development of phospholipid nanoparticles encapsulating 3-O-cetyl ascorbic acid and tocopherol acetate (TA-Cassome) for improving their skin accumulation.

Phospholipid nanoparticles (PNs) encapsulating vitamin C and E derivatives, 3-O-cetyl ascorbic acid (CA) and tocopherol acetate (TA), respectively, were examined using the film rehydration and extrusion method. PN formulations (TA-Cassome) were prepared by mixing CA, soya phosphatidylcholine (Soya PC), sodium cholate, and TA at a molar ratio of 20/80/5/6. Glycerol (GL) or diglycerol (DG) were also added to improve the skin accumulation of CA and TA. Three TA-Cassome formulations were evaluated using a dynamic light scattering (DLS), NMR, TEM, skin accumulation test for CA and TA, and small-angle X-ray diffraction (SAXD) analysis. TA-Cassome formulations (150 nm) were stable for two weeks and they encapsulated 1.8 mg/mL of TA. TEM and SAXD analysis revealed that the nanoparticles formed a spherical multilayer structure. 1H and 31P NMR indicated that GL and DG enhanced the proton mobility of choline groups of soya PC molecules located on the membrane surface of TA-Cassome. Accumulation of CA and TA in the dermis was increased by adding GL and DG. SAXD analysis revealed that GL and DG promoted the formation of new lamellar structures on the stratum corneum, which contributed to improving the skin accumulation of CA and TA.

Characterization and Evaluation of Skin Permeation of Tocopheryl Phosphoric Acid-loaded Phospholipid Nanoparticles.

Tocopheryl phosphoric acid (TPA, a hydrophilic vitamin E derivative) loaded liposome and glycerin containing phospholipid nanoparticles (GPLNP) were prepared using the film rehydration and extrusion method. Nanoparticle formulations were evaluated for size, zeta potential, and in vitro permeation across hairless mouse skin, and 31P NMR spectral analysis was performed. The prepared formulations were stable for 2 weeks, and their mean nanoparticle size varied between 90 and 140 nm. Although glycerin did not affect the particle size of the empty (no TPA) system, TPA-loading resulted in the reduction of particle size and conferred a negative charge. The 31P NMR spectral analysis showed that the presence of glycerin in the formulation changed the nanoparticle structure from a bilayer to a nonbilayer. Moreover, it was suggested that TPA molecules interacted with phospholipid by entrapping nanoparticles in the formulations. TPA did not permeate across the hairless mouse skin after 48 h. However, the TPA concentration in the hairless mouse skin after permeation study increased in the nanoparticle systems and the 30% GPLNP formulation was the best formulation for the accelerated TPA permeation in the hairless mouse skin. These results demonstrate that 30% GPLNP improved TPA permeation in the hairless mouse skin model. And it was strongly suggested that glycerin has an important role for changing the structure of nanoparticles and enhancing the skin permeation of TPA.

Immunogenicity of protein aggregates of a monoclonal antibody generated by forced shaking stress with siliconized and nonsiliconized syringes in BALB/c mice.

OBJECTIVE: In this study, we aimed to investigate the immunogenicity of protein aggregates of monoclonal antibodies (mAbs), generated by forced shaking stress with siliconized and nonsiliconized syringes in a mouse model. METHODS: Samples were filled in siliconized and nonsiliconized syringes with shaking and headspace air. Characterization studies were performed using high-performance size-exclusion chromatography, nanoparticle tracking analysis, flow cytometry, micro-flow imaging and resonant mass measurement. The samples (10 or 100 µg) were subcutaneously injected into BALB/c mice for 21 days, and the anti-drug antibody (ADA) concentrations were monitored. KEY FINDINGS: In samples shaken with siliconized syringes [SO (+)], large amounts of submicron and subvisible protein aggregates were formed by interactions with silicone oil droplets. The characteristics of protein aggregates differed between the mAb solution and shaken samples, which strongly indicates that silicone oil accelerates protein aggregation. When administered at low doses, the ADA concentration in all samples increased with repeated injections, and SO (+) induced the highest immunogenicity. However, when administered at high doses, ADA concentration decreased following prolonged repeated administration for tolerance. CONCLUSIONS: These results indicated that mAb protein aggregation induced immunogenicity in mice, and SO (+) induced higher immunogenicity than samples shaken with nonsiliconized syringe.

Influence of molecular weight and structure on diffusion rates and mechanisms of dextran polyelectrolyte complexes.

The release profiles of fluorescein isothiocyanate-dextran (FD) at various molecular weights (20-500kDa) and the swelling behaviors of polyelectrolyte complex-forming tablets were investigated. Four types of tablets were prepared using different combinations of the following chemicals: carboxymethyl dextran (CMD), dextran sulfate (DS), 2-diethylaminoethyl dextran (EA), and 2-hydroxypropyltrimethylammonium dextran (CDC). Release tests were conducted via the rotating basket method at pH 6.8. Swelling behaviors were analyzed via the front movement method. For all FDs, release rates decreased with decreasing density of charged groups in the matrix, as follows: CMD-EA, CMD-CDC, DS-EA, and DS-CDC. Front movement profiles showed that the dried core disappeared within 3h, leaving the swollen matrix. Results revealed that the tablets rapidly formed hydrated matrices, with release of the incorporated FDs by diffusion and erosion. The tablets successfully released the macromolecules, and we determined that the release rates could be controlled with a combination of dextran derivatives.

Modulation mechanism of the stratum corneum structure during permeation of surfactant-based rigid and elastic vesicles.

We evaluated the interaction between human stratum corneum (SC) and surfactant-based rigid or elastic vesicles during permeation using synchrotron X-ray diffraction to obtain the mechanism action of surfactant-based vesicles for enhanced skin permeation. The effects of vesicle elasticity on the interaction with SC were also investigated. Changes in the small-angle X-ray diffraction peaks of the human SC after buffer control and vesicle application were monitored. In the small-angle region, the control as the citrate buffer induced no significant changes of diffraction peaks for the lamellar structure of short periodicity phase (SPP), which is observed as a main peak in the human SC. Application of rigid vesicles resulted in small changes in the diffraction peaks attributed to lamellar phase of SPP. After application of elastic vesicles, however, a large shift to smaller angles due to swelling of the lamellar phase of SPP was clearly observed from the intensity difference profiles. All peaks due to the vesicles were still observed after 2h of application for all formulations, indicating that both vesicles interacted with the SC while maintaining their structures. These results strongly suggest that vesicles affect the lamellar phase of SPP of the intercellular lipids in the SC during permeation.

Application of Response Surface Methodology to Estimate the Design Space of Pharmaceutical Diluents for Dispensing Powdered Formulations.

Scientific approaches for dispensation are important for the quality and efficacy of drug treatments. Therefore, for the dispensation of powdered medicines, we have developed a powder blending method using a planetary centrifugal mixer (PCM) to replace the empirical manual method involving a mortar and pestle. The aim of this study was to optimize the formulation of pharmaceutical diluents for dispensing powdered medicines, using PCM. The diluents, composed of powdered lactose, crystalline lactose, and corn starch were assigned to a {3,2}-Simplex Lattice design. Then, the designed diluents were blended with model powders, such as carbazochrome sodium sulfonate powder, rifampicin capsule contents, and crushed sulfasarazine tablets, at ratios of 1 : 4, 1 : 1, and 4 : 1 using PCM at 800 rpm for 60 s at a 20% filling rate. The mixtures were examined for content uniformity relative standard deviation (RSD) and flowability angle of repose (AOR). Response surface methodology was applied to optimize the formulation with the smallest RSD and AOR, and then the design space of desired diluents was estimated. On the basis of the design space, crystalline lactose, the mixture of lactose powder and crystalline lactose at a ratio of 1 : 4, and the mixture of corn starch and crystalline lactose at a ratio of 1 : 4, were suitable diluents for the powdered formulation, the content of the capsules, and the crushed tablets, respectively. The selected diluents were successfully applied to other model medicines showing a sufficient RSD and AOR. This technique could contribute to the development of scientific approaches for dispensation.

Dry Powder Coating using Planetary Centrifugal Mixer.

PURPOSE: Extemporaneous compounding is an important part of pharmacy practice, and should be standardized and sophisticated to ensure the quality of the compounded preparations. Recently, we applied a planetary centrifugal mixer (PCM) to powder blending, which has attracted interest for its small scale and lack of contamination. In this study, we aimed to reveal the feasibility of dry powder coating through ordered mixing of fine particles using PCM. METHODS: Cohesive lactose powders (Pharmatose450M) were dry coated with magnesium stearate (MgSt) using from 0.1 to 5%(w/w) content. The operational variables tested were operation time (1-30 min), operation speed (400-1000 rpm), vessel size (24-100 mL), and charging rate in the vessel (20-40%). The processed powders were evaluated for their surface morphology, flowability, and wettability. Furthermore, fine ibuprofen particles were coated with various lubricants, and then the dissolution profiles were examined. The crystallinity of ibuprofen was assessed using FT-IR and PXRD. RESULTS: Lactose powders were successfully coated with MgSt using PCM. When the level of MgSt was over 1%, the surface of the lactose powders was thoroughly covered. Angles of repose were 51° and 41° for unprocessed and processed powders with 1% MgSt, respectively. The contact angle of the water drop on the 1% MgSt sample leached to be 132°, changing to a hydrophobic surface. Investigations under various operational conditions revealed that higher improvement was observed upon higher speed and longer time, and a smaller charging rate in the vessel. Vessel size had no impact. Moreover, improved dissolution of ibuprofen coated with both hydrophilic and hydrophobic lubricants was observed owing to good dispersing behavior. Besides, no alteration of crystallinity was detected. CONCLUSIONS: PCM is an effective tool for dry powder coating with low impact stress. The presented method will contribute a great deal to making crushed tablets a functional powder.

Reconstitution of L-Asparaginase in Siliconized Syringes with Shaking and Headspace Air Induces Protein Aggregation.

The aim of this study was to characterize protein aggregation during reconstitution of a highly concentrated solution of lyophilized L-asparaginase (L-ASP). The effect of the preparation method on L-ASP aggregation using siliconized or non-siliconized syringes and the effect of storage after preparation were evaluated by far-UV circular dichroism spectroscopy, Raman microscopy, flow cytometry, and flow particle image analysis. To investigate the effect of syringe type in combination with shaking and headspace air on L-ASP aggregation, four kinds of L-ASP in 5% glucose solutions were prepared (in the presence or absence of silicon oil and headspace air). Slight differences in L-ASP secondary structure were observed between the siliconized and non-siliconized syringe systems before shaking. Large numbers of sub-visible (0.1-100 µm) and submicron (0.1-1 µm) particles were formed by preparation with siliconized syringes and the combination of shaking and headspace air. The number of aggregated particles was not decreased with increased storage time. The Raman microscopy, flow cytometry and flow particle image results suggested that L-ASP interacted with silicone oil, which induced aggregation. Nevertheless, sub-visible and submicron particles were also formed with non-siliconized syringes. However, using non-siliconized syringes, the number of aggregated particles decreased with storage. No changes in particle character were observed before or after shaking with headspace air in non-siliconized syringes, indicating that soluble aggregates formed and dissolved with storage. Silicone oil in syringes, in combination with shaking and headspace air, strongly affected the aggregation of lyophilized L-ASP formulations during preparation.

Glyceryl monooleyl ether-based liquid crystalline nanoparticles as a transdermal delivery system of flurbiprofen: characterization and in vitro transport.

Liquid crystalline nanoparticles (LCNs) were prepared using glyceryl monooleyl ether (GME) by the modified film rehydration method. Hydrogenated lecithin (HL), 1,3-butylene glycol (1,3-BG), and Poloxamer 407 were used as additives. The prepared LCN formulations were evaluated based on particle size, small-angle X-ray diffraction (SAXS) analysis, (1)H- and (19)F-NMR spectra, and in vitro skin permeation across Yucatan micropig skin. The composition (weight percent) of the LCN formulations were GME-HL-1,3-BG (4 : 1 : 15), 4% GME-based LCN and GME-HL-1,3-BG (8 : 1 : 15), 8% GME-based LCN and their mean particle sizes were 130-175 nm. Flurbiprofen 5 and 10 mg was loaded into 4% GME-based LCN and 8% GME-based LCN systems, respectively. The results of SAXS and NMR suggested that both flurbiprofen-loaded formulations consist of particles with reverse type hexagonal phase (formation of hexosome) and flurbiprofen molecules were localized in the lipid domain through interaction of flurbiprofen with the lipid components. Flurbiprofen transport from the LCN systems across the Yucatan micropig skin was increased compared to flurbiprofen in citric buffer (pH=3.0). The 8% GME-based LCN systems was superior to the 4% GME-based LCN for flurbiprofen transport. Since the internal hexagonal phase in the 8% GME-based LCN systems had a higher degree of order compared to the 4% GME-based LCN in SAXS patterns, the 8% GME-based LCN system had a larger surface area, which might influence flurbiprofen permeation. These results indicated that the GME-based LCN system is effective in improving the skin permeation of flurbiprofen across the skin.