The production of a lyotropic liquid crystal coated powder precursor through twin screw extrusion.

Likhar, Lokesh

January 2013

The twin screw extrusion technique has been explored to produce lyotropic liquid crystal coated powder precursor by exploiting Pluronic F127 thermoreversible gelation property to get powder precursor without granular aggregates or with less compacted granular aggregates. The highly soluble chlorpheniramine maleate loaded in Pluronic F127 solution coated MCC particles prepared through twin screw extrusion was examined to produce the cubic phase (gel) for the development of controlled release formulation and for coating of very fine particles which cannot be achieved by traditional bead coaters. Controlled release formulations are beneficial in reducing the frequency of administration of highly soluble drugs having short half life and also to address the problem of polypharmacy in old age patients by reduction of dosage frequency. An unusual refrigerated temperature (5 C) profile for twin screw extrusion was selected based on the complex viscoelastic flow behaviour of Pluronic F127 solution which was found to be highly temperature sensitive. The Pluronic F127 solution was found to be Newtonian in flow and less viscoelastic at low temperature, such that low temperature (5 C) conditions were found to be suitable for mixing and coating the MCC particles to avoid compacted aggregates. At higher temperatures (35-40 C) Pluronic F127 solution exhibited shear thinning and prominent viscoelasticity, properties which were exploited to force CPM containing Pluronic F127 solution to stick over the MCC surface. This was achieved by elevating the temperature of the last zone of the extrusion barrel. It was found that to avoid compacted aggregates the MCC must be five times the weight of the Pluronic F127 solution and processed at a screw speed of 400 RPM or above at refrigerated temperature. Processing was not found to be smooth at ambient temperature with frictional heat and high torque generation due to significant compaction of coated particles which can be attributed to the elastic behaviour of Pluronic F127 solution at temperatures between ambient to typical body temperature. PLM images confirmed the cubic phase formation (gel) by Pluronic F127 coating which was found to be thick with maximum Pluronic F127 concentration (25%). SEM images showed smoothing of surface topography, and stretching and elongation of MCC fibres after extrusion which is indicative of coating through extrusion processing. Plastic deformation was observed for the lower Pluronic F127 concentration and higher MCC proportions. There was a significant decrease in work done for cohesion by the powder flow analyser observed in the batches with more aggregates compared with batches with least aggregates. A regression analysis study on factorial design batches was conducted to investigate the significant independent variables and their impact on dependent variables for example % torque, geometric mean diameter and work done for cohesion, and to quantitatively evaluate them. From the regression analysis data it was found that the coefficient of determination for all three dependent variables was in the range of 55-62%. The pharmaceutical performance of the prepared coated LLC precursor through twin screw extrusion in terms of controlled release was found to be very disappointing. Almost 100% chlorpheniramine maleate was released within 10-15mins, defined as providing burst release. The MDSC method was developed within this work to detect Pluronic F127 solution cubic phase formation. The MDSC method was developed to consider sample size, effect of heating and cooling, sample heat capacity, and the parameters for highest sensitivity which can be followed by sample accurately without the phase lag to produce accurate repeatable results.

Lyotropic liquid crystal

Twin screw extrusion

Pluronic F127

Chlorpheniramine maleate

Microcrystalline cellulose

Cubic phase

MDSC

PLM

SEM

Work done for cohesion

Geometric mean diameter

Liquid crystalline phase as a probe for crystal engineering of lactose: carrier for pulmonary drug delivery

Patil, S.S., Mahadik, K.R., Paradkar, Anant R

02 1900

No / The current work was undertaken to assess suitability of liquid crystalline phase for engineering of lactose crystals and their utility as a carrier in dry powder inhalation formulations. Saturated lactose solution was poured in molten glyceryl monooleate which subsequently transformed into gel. The gel microstructure was analyzed by PPL microscopy and SAXS. Lactose particles recovered from gels after 48 h were analyzed for polymorphism using techniques such as FTIR, XRD, DSC and TGA. Particle size, morphology and aerosolisation properties of prepared lactose were analyzed using Anderson cascade impactor. In situ seeding followed by growth of lactose crystals took place in gels with cubic microstructure as revealed by PPL microscopy and SAXS. Elongated (size approximately 71 mum) lactose particles with smooth surface containing mixture of alpha and beta-lactose was recovered from gel, however percentage of alpha-lactose was more as compared to beta-lactose. The aerosolisation parameters such as RD, ED, %FPF and % recovery of lactose recovered from gel (LPL) were found to be comparable to Respitose(R) ML001. Thus LC phase (cubic) can be used for engineering of lactose crystals so as to obtain particles with smooth surface, high elongation ratio and further they can be used as carrier in DPI formulations.

Administration

Inhalation

Calorimetry

Differential scanning

Chemistry

Pharmaceutical

Crystallization

Drug Carriers

Glycerides

Lactose

Liquid Crystals

Microscopy

Particle Size

Powder diffraction

Scattering

Small angle spectroscopy

Fourier transform Infrared

Thermogravimetry

X-ray diffraction

Cascade impactor

Cubic phase

Glyceryl monooleate

Lactose monohydrate

Salbutamol sulfate

Photon Upconversion Sensitized Rare-Earth Fluoride Nanoparticles

Monks, Melissa-Jane

26 June 2023

Aufkonversions-Nanokristalle (UCNC) zeichnen sich als einzigartige Lumineszenzreporter aus, die Nah-infrarotes Anregungslicht in Photonen höherer Energie umwandeln. Für die gezielte Anpassung von Eigenschaften, bedarf es ein tiefes Verständnis der Prozesse der Aufwärtskonversionslumineszenz (UCL) und deren Abhängigkeit von Material und Partikeldesign. Diese Doktorarbeit untersucht die UCL-Prozesse von Yb3+,Er3+ dotierten SrF2-UCNC und zielt darauf ab, die UCL-Eigenschaften der bisher unterschätzten kubischen Wirtsgitter zu verstehen und zu steigern. Hierbei wird die fluorolytische Sol-Gel-Synthese als neuartige Syntheseroute für UCNC vorgestellt. Vorteile wie ausgezeichnete Reproduzierbarkeit, viele Freiheitsgrade bei der Temperaturbehandlung und Partikelgestaltung werden anhand von SrF2 UCNC demonstriert. Die UCNC wurden mittels UCL-Spektren, UCL-Quantenausbeuten, leistungsdichte-abhängiger relativer spektraler Verteilung sowie der Lumineszenzabklingkinetiken unter Einbeziehung kristalliner Eigenschaften wie der Kristallphase, der Kristallitgröße, der Gitterparameter und der Teilchengröße untersucht. Die Abhängigkeit der UCL-Eigenschaften von der Dotierungsmenge wurde mit einer umfassenden Dotierungsreihe beschrieben und der optimale Dotierungsbereich (Yb3+,Er3+) von kleinen, ungeschalten SrF2-UCNC eingegrenzt. Bei der Studie dotierter Kerne mit passivierenden Schalen wurde der Einfluss von Temperaturbehandlung auf die UCL-Mechanismen und die Kern-Schale-Vermischung untersucht. Anhand von unterschiedlich kalzinierten UCNC Pulvern wurde die Empfindlichkeit der UCL gegenüber der Änderung kristalliner Eigenschaften, wie Kristallphase, Kristallinität, und Kristallitgröße betrachtet. Zusammen liefern die Dotierungs-, die Kern-Schale- und die Kalzinierungsstudie wertvolle Einblicke in das gitterspezifische Verhalten der UCL-Eigenschaften als Funktion der Energiemigration und der Kristalleigenschaften. / Upconversion nanocrystals (UCNC) represent a unique type of luminescence reporters that convert near-infrared excitation light into higher energy photons. Tailoring UCNC with specific luminescence properties requires an in-depth understanding of upconversion luminescence (UCL) processes and their dependence on material and particle design. This Ph.D. thesis focuses on the UCL processes of Yb3+,Er3+ doped SrF2-UCNC and aims to understand and enhance the UCL properties of the previously underestimated cubic host lattices. Herein, fluorolytic sol-gel synthesis is introduced as a novel synthetic route for UCNC. Advantages such as excellent reproducibility, high flexibility in temperature treatment and particle design are demonstrated using SrF2 UCNC. The UCNC were characterized by UCL spectra, UCL quantum yields, excitation power density-dependent relative spectral distribution, and luminescence decay kinetics involving crystalline properties such as crystal phase, crystallite size, lattice parameters, and particle size. The dependence of UCL properties on doping amount was described in a comprehensive doping study, and the optimal doping range (Yb3+,Er3+) of small, unshelled SrF2-UCNC was identified. In a core-shell study of doped core UCNC with passivating shells, the influence of temperature treatment on UCL mechanisms and core-shell mixing was investigated. Further, using different calcined UCNC powders, the sensitivity of UCL to the change of crystalline properties, such as crystal phase, crystallinity, and crystallite size, was assessed. Together, the doping, core-shell, and calcination studies provide valuable insight into the lattice-specific behavior of UCL properties as a function of energy migration and crystal properties.

Aufkonversionslumineszenz

Lumineszenzsabklingzeiten

Lumineszenzlöschung

Fluorolytische Sol-Gel-Synthese

Strontiumfluorid

Ytterbium

Erbium

Anregungsleistungsdichte

Kernschalepartikel

Nanokristalle

Nanopartikel

Aufkonversionslumineszenzquantenausbeute

lanthanide-doped nanocrystals

upconversion luminescence

luminescence decay

luminescence microenvironment

lanthanide doping

Erbium

Ytterbium

Strontium Fluoride

fluorolytic sol-gel synthesis

nanocrystals

nanoparticle

core shell intermixing

passivating shell

calcination study

annealing study

cubic phase UCNC

Ytterbium clustering

Calcium Fluoride

UCL spectra

relative spectral distribution

NIR emission

Doping Series

upconversion luminescence quantum yields

Yb-Yb energy migration

NaYbF4

SrF2

CaF2

Yb3+, Er3+ co-doping

546 Anorganische Chemie

541 Physikalische Chemie

VG 8757

VE 8007

VH 8010

VH 8061

VH 8059

ddc:546

ddc:541