Pluronic F127 thermosensitive injectable smart hydrogels for controlled drug delivery system development

Shriky, Banah, Kelly, Adrian L., Isreb, Mohammad, Babenko, Maksims, Mahmoudi, N., Rogers, S., Shebanova, O., Snow, T., Gough, Timothy D.

2019 December 1923

Yes / Understanding structure-property relationships is critical for the development of new drug delivery systems. This study investigates the properties of Pluronic smart hydrogel formulations for future use as injectable controlled drug carriers. The smart hydrogels promise to enhance patient compliance, decrease side effects and reduce dose and frequency. Pharmaceutically, these systems are attractive due to their unique sol-gel phase transition in the body, biocompatibility, safety and injectability as solutions before transforming into gel matrices at body temperature. We quantify the structural changes of F127 systems under controlled temperature after flow, as experienced during real bodily injection. Empirical formulae combining the coupled thermal and shear dependency are produced to aid future application of these systems. Induced structural transitions measured in-situ by small angle x-ray and neutron scattering reveal mixed oriented structures that can be exploited to tailor the drug release profile.

Thermosensitive

Gel

Thermal properties

Rheological properties

SAXS

SANS

Drug release

Pluronic

Colloidal crystals

Drug delivery systems

Injectables

Poloxamer

Quantifying nisin adsorption behavior at pendant polyethylene oxide brush layers

Dill, Justen K.

01 June 2012

A more quantitative understanding of peptide loading and release from polyethylene oxide (PEO) brush layers will provide direction for development of new strategies for drug storage and delivery. The antimicrobial peptide nisin shows potent activity against Gram-positive bacteria including the most prevalent implant-associated pathogens, its mechanism of action minimizes the opportunity for the rise of resistant bacteria and it does not appear to be toxic to humans, suggesting good potential for its use in antibacterial coatings for selected medical devices. In this work, optical waveguide lightmode spectroscopy was used to record changes in adsorbed mass during cyclic adsorption-elution experiments with nisin, at uncoated and PEO-coated surfaces. PEO layers were prepared by radiolytic grafting of Pluronic® surfactant F108 or F68 to silanized silica surfaces, producing long- or short-chain PEO layers, respectively. Kinetic patterns were interpreted with reference to a model accounting for history-dependent adsorption, in order to evaluate rate constants for nisin adsorption and desorption, as well as the effect of pendant PEO on the lateral clustering behavior of nisin. Lateral rearrangement and clustering of adsorbed nisin was apparent on uncoated and F68-coated surfaces, but not on F108-coated surfaces. In addition, nisin showed greater resistance to elution by peptide-free buffer from uncoated and F68-coated surfaces. These results are consistent with shorter PEO chains allowing for peptide adsorption to the base substrate in the case of F68-coated surfaces, while adsorption to the F108-coated surfaces is apparently governed by the presence of a hydrophobic core within the brush layer itself. Further, these results suggest that while peptide location within the hydrophobic core provides stability against lateral rearrangement, the pendant PEO chains themselves provide no steric barrier to nisin rearrangement within the brush layer. / Graduation date: 2012

Protein

Adsorption

Nisin

Polyethylene

Oxide

Optical

Waveguide

Lightmode

Spectroscopy

Pluronic

F108

F68

Brush

Layer

PEO

Nisin -- Absorption and adsorption

Implants, Artificial

Drug delivery systems

Coatings

Retention of protein repulsive character and antimicrobial activity of PEO brush layers following nisin entrapment

Auxier, Julie A.

30 November 2012

Nisin, an amphiphilic, antimicrobial peptide, has been shown to integrate into the hydrophobic inner region of poly(ethylene oxide) (PEO) brush layers; however, the presence of integrated nisin may compromise the protein repulsive character of the PEO layer. In particular, the introduction of fibrinogen to nisin-loaded brush layers has been observed to cause changes consistent with partial elution of nisin and/or location of fibrinogen at the interface. Questions surrounding the possibility of fibrinogen adsorption warrant further investigation, as the location of procoagulant proteins at a peptide-loaded PEO layer would significantly reduce the viability of a medical device coating based on such an approach. In this work, the preferential location of fibrinogen at PEO brush layers was investigated by: detection of FITC-labeled fibrinogen after sequential introduction of nisin and labeled fibrinogen; measurement of changes in the zeta potential of PEO coated and uncoated surfaces following nisin, fibrinogen, and/or buffer challenges; and evaluation of adsorption and elution kinetics in label-free, sequential adsorption experiments using optical waveguide lightmode spectroscopy (OWLS). PEO layers were constructed through radiolytic grafting of Pluronic�� F108 or F68 onto silanized silica surfaces producing long-chain or short-chain PEO layers, respectively. Adsorption results indicated that sequential introduction of nisin and fibrinogen to PEO brush layers, based on F108, does not result in fibrinogen adsorption beyond that expected for a nisin-free PEO layer. No evidence of nisin entrapment in fibrinogen-repellent F68 layers was recorded. Low-level fibrinogen adsorption observed at F68 layers following the introduction of nisin was determined to be a result of nisin adsorption at (uncoated) defect regions on the surface. In conclusion, retention of PEO layer capacity for protein repulsion after nisin entrapment is owing to a steric repulsive barrier provided by PEO segments extending beyond the level of entrapped nisin. It was then hypothesized that the immobilized, pendant PEO chains will inhibit exchange of entrapped nisin by competing proteins, and therefore prolong nisin activity retention. In order to evaluate nisin function following its entrapment, the antimicrobial activity of nisin-loaded, F108-coated silica surfaces was evaluated against the Gram-positive indicator strain, Pediococcus pentosaceous. The retained biological activity of these nisin-loaded layers was evaluated after incubation in the presence of bovine serum albumin (BSA), for contact periods up to one week. Surfaces were withdrawn at selected times and placed on plates inoculated with P. pentosaceous to measure kill zone radius in order to quantify nisin activity. In the presence of BSA, F108-coated surfaces retained more antimicrobial activity than the uncoated, hydrophobic surfaces. These results strongly suggest that PEO brush layers may serve as a viable drug storage platform due to the retained non-fouling character after bioactive peptide entrapment and the prolonged peptide activity in the presence of other proteins. / Graduation date: 2013

nisin adsorption

fibrinogen repulsion

Pluronic�� F108

PEO brush layer

optical waveguide lightmode spectroscopy

nisin activity

Nisin -- Absorption and adsorption

Fibrinogen

Polyethylene oxide

Microdialysis Sampling of Macro Molecules : Fluid Characteristics, Extraction Efficiency and Enhanced Performance

Chu, Jiangtao

January 2015

In this thesis, fluid characteristics and sampling efficiency of high molecular weight cut-off microdialysis are presented, with the aim of improving the understanding of microdialysis sampling mechanisms and its performance regarding extraction efficiency of biological fluid and biomarkers. Microdialysis is a well-established clinical sampling tool for monitoring small biomarkers such as lactate and glucose. In recent years, interest has raised in using high molecular weight cut-off microdialysis to sample macro molecules such as neuropeptides, cytokines and proteins. However, with the increase of the membrane pore size, high molecular weight cut-off microdialysis exhibits drawbacks such like unstable catheter performance, imbalanced fluid recovery, low and unstable molecule extraction efficiency, etc. But still, the fluid characteristics of high molecular weight cut-off microdialysis is rarely studied, and the clinical or in vitro molecule sampling efficiency from recent studies vary from each other and are difficult to compare.   Therefore, in this thesis three aspects of high molecular weight cut-off microdialysis have been explored. The first, the fluid characteristics of large pore microdialysis has been investigated, theoretically and experimentally. The results suggest that the experimental fluid recovery is in consistency with its theoretical formula. The second, the macromolecule transport behaviour has been visualized and semi-quantified, using an in vitro test system and fluorescence imaging. The third, two in vitro tests have been done to mimic in vivo cerebrospinal fluid sampling under pressurization, using native and differently surface modified catheters. As results, individual protein/peptide extraction efficiencies were achieved, using targeted mass spectrometry analysis. In summary, a theory system of the fluid characteristics of high molecular weight cut-off microdialysis has been built and testified; Macromolecular transport of microdialysis catheter has been visualized; In vivo biomolecules sampling has been simulated by well-defined in vitro studies; Individual biomolecular extraction efficiency has been shown; Different surface modifications of microdialysis catheter have been investigated. It was found that, improved sampling performance can be achieved, in terms of balanced fluid recovery and controlled protein extraction efficiency.

microdialysis

high molecular weight cut-off

fluid characteristics

fluid recovery

extraction efficiency

biomarker

microporous membrane

macromolecule transport

transmembrane

large pore

surface modification

pluronic

dextran

in vitro

microdialysis catheter

Développement de systèmes d'administration originaux destinés à la prévention de la contamination par le VIH chez la femme

Aka, Armelle Adjoua Sandrine

14 June 2012

Avec près de 30 millions de morts depuis le début de la pandémie, l'infection par le VIH est un véritable fléau à l'échelle mondiale, surtout en Afrique sub-saharienne. Dans ce contexte, disposer d'une formulation microbicide efficace, facile à administrer par la voie vaginale, représenterait un outil de prévention idéal pour lutter contre cette pandémie. Ainsi, la conception rationnelle de telles formulations représente un enjeu majeur de santé publique.Ce travail décrit la recherche de formulations thermogélifiantes et mucoadhésives à base de pluronics et d'hydroxypropyl méthylcellulose (HPMC). Outre la caractérisation de leurs propriétés rhéologiques et d'adhésion, ainsi que des études en culture cellulaire suggérant une très faible toxicité de contact, ces hydrogels ont montré d'une part, leur capacité à véhiculer efficacement le peptide M48U1 (équipe L. Martin, CEA) destiné à bloquer l'entrée cellulaire du VIH et d'autre part à ralentir considérablement la diffusion de nanoparticules modèles mimant les particules virale matures du VIH-1, en comparaison d'hydrogel d'hydroxy éthylcellulose (HEC) fréquemment utilisés dans divers essais cliniques infructueux et aussi au mucus cervico-vaginal de macaque. L'ensemble des résultats suggère donc la capacité de ces formulations à constituer une double barrière, physique et pharmacologique, protectrice de la muqueuse vaginale vis-à-vis du VIH.

Systèmes thermogélifiants

Pluronic

VIH-1

Vidéo-microscopie

Diffusivité nanoparticulaire

Microbicides

M48U1

Profil de libération

Voie vaginale

Mesostructured particulate silica materials with tunable pore size : Synthesis, characterization and applications

Sörensen, Malin Helena

January 2009

Colloidal assemblies of surfactants and polymers in aqueous solutions have been used by human mankind for hundreds of years and they are of great importance in many of our technological processes, such as fabrication of soap and papermaking. Less than two decades ago the idea of using colloidal assemblies as templates of inorganic materials was borne. A new population of materials, referred to as surfactant templated materials, took form. These materials showed extraordinary properties such as monodisperse pore size distribution, large surface areas and pore volumes.   The main focus of this thesis has been on synthesis and functionalisation of spherical mesostructured silica particulate materials. In the first part of the work, mesostructured materials with expanded pores have been produced using a well established aerosol-based method as well as the newly developed emulsion and solvent evaporation (ESE) method. Increase in pore size was realized through using Pluronic block copolymer F127 together with a swelling agent poly(propylene glycol) as template. The influence of the swelling agent on pore size expansion was shown to have a roughly linear relationship. Furthermore, the impact of synthesis parameters on internal and exterior morphology has been investigated. Accessibility of the internal pore space, as well as the external surface roughness were shown to be highly dependent on synthesis temperature. Additionally, a very interesting well ordered 3D closed packed (P63/mmc) material was produced using the ionic surfactant C16TAB as template in the ESE method.   In the second part of the thesis work, mesoporous spheres with large pore size, having either hydrophilic or hydrophobic surface properties, were used as carriers of an enzyme, lipase. The enzymatic activity of lipase was increased onto the hydrophobic surface, compared to lipase immobilized into the hydrophilic support as well as for lipase free in solution. This effect was probably due to a combination of enhanced hydrophobic interactions preventing denaturation of the enzyme and interfacial activation of the enzyme.  This study generated an inorganic carrier material that is a promising candidate for biocatalysis applications. Additionally, mesoporous spheres were used as carriers of a model drug, Ibuprofen, to study the effect of polyelectrolyte multilayers on release properties. However, these layers were shown impermeable independent on pH and the substance was only released from uncoated particles. / <p>QC 20100811</p>

Mesoporous materials

aersol-based process

emulsion-based process

biocatalysis

sustained release

3D hexagonal

2D hexagonal

powder

spherical particles

liquid crystalline phases

AFM-porosimetry

Pluronic

Chemistry

Kemi

Pluronic Activity in Hyperthermia-induced Cancer Cell Death

Dremann, David Michael

26 August 2009

No description available.

Biology

Biomedical Research

Cellular Biology

Engineering

Molecular Biology

Oncology

Pharmaceuticals

Polymers

Pluronic

HSP70

Hyperthermia

Thermosensitization

Cancer

Colorectal

Suppression

Polymer

Surfactant

Pharmaceutical

Stabilized Nanobubbles for Diagnostic Applications

Hernandez, Christopher

01 June 2018

No description available.

Biomedical Engineering

nanobubbles

microbubbles

ultrasound contrast agents

molecular imaging

cancer

diagnostic ultrasound

nanoparticles

surface tension

Langmuir-Blodgett

pendant drop

cryo-EM

Pluronic

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