A kinetic study of the degradation of hyaluronic acid at high concentrations of sodium hydroxide

Lekander, Maria, Fagerström Troncoso, Jonathan, Idjbara, Abdelrahman, Karlsson, Ida, Lindgren, Teresia, Ström, Simon

January 2016

During production of different Hyaluronic acid (HA) products Galderma use a high concentration of NaOH in the crosslinking process of HA. HA’s degradation kinetics are widely unknown at higher pH’s and is interesting for the future of product development of HA. Static Light Scattering (SLS) was used to determine the weight average molecular weight (MW ) of samples with four different NaOH concentrations, four temperatures, three reaction times and one t0  sample. The results were evaluated in forms of Arrhenius-graphs for different NaOH concentrations, the activation energy (EA ) with respect to pH and the reaction rate for each temperature with respect to NaOH concentration. It was found that the degradation of HA was more strongly affected by temperature than by NaOH concentration and that the EA  did not show any significant signs of change between higher concentrations of NaOH.

Hyaluronic acid

cross linking

sodium hydroxide

pH

Arrhenius

kinetics

degradation

static light scattering

Detection of Light Scattering for Lab-On-A-Chip Immunoassays Using Optical Fibers

Lucas, Lonnie J.

January 2007

This dissertation develops technology for microfluidic point-of-care immunoassay devices. This research (2004–2007) improved microfluidic immunoassay performance by reducing reagent consumption, decreasing analysis time, increasing sensitivity, and integrating processes using a lab-on-a-chip. Estimates show that typical hospital laboratories can save $1.0 million per year by using microfluidic chips. Our first objective was to enhance mixing in a microfluidic channel, which had been one of the main barriers to using these devices. Another goal of our studies was to simplify immunoassays by eliminating surfactants. Manufacturers of latex immunoassays add surfactants to prevent non-specific aggregation of microspheres. However, these same surfactants can cause false positives (and negatives) during diagnostic testing. This work, published in Appendix A (© 2006 Elsevier) shows that highly carboxylated polystyrene (HCPS) microspheres can replace surfactants and induce rapid mixing via diffusion in microfluidic devices. Our second objective was to develop a microfluidic device using fiber optics to detect static light scattering (SLS) of microspheres in Appendix B (© 2007 Elsevier). Fiber optics were used to deliver light emitting diode (LED) or laser light. A miniature spectrometer was used to measure 45° forward light scattering collected by optical fiber. Latex microspheres coated with PR3 proteins were used to test for the vasculitis marker, anti-PR3. No false negatives or positives were observed. A limit of detection (LOD) of 50 ng mL⁻¹ was demonstrated. This optical detection system works without fluorescence or chemiluminescence markers. It is cost effective, small, and re-usable with simple rinsing. The final objective in this dissertation, published in Appendix C (© 2007 Elsevier), developed a multiplex immunoassay. A lab-on-a-chip was used to detect multiple antibodies using microsphere light scattering and quantum dot (QD) emission. We conjugated QDs onto microspheres and named this configuration “nano-on-micro” or “NOM”. Upon radiation with UV light, strong light scattering is observed. Since QDs also provide fluorescent emission, we are able to use increased light scattering for detecting antigen-antibody reactions, and decreased QD emission to identify which antibody is present.

multiplex assay

immunoagglutination

static light scattering

on-chip detection

quantum dots

microfluidic device

CHARACTERIZATION OF COLLOIDAL NANOPARTICLE AGGREGATES USING LIGHT SCATTERING TECHNIQUES

Kozan, Mehmet

01 January 2007

Light scattering is a powerful characterization tool for determining shape, size, and size distribution of fine particles, as well as complex, irregular structures of their aggregates. Small angle static light scattering and elliptically polarized light scattering techniques produce accurate results and provide real time, non-intrusive, and in-situ observations on prevailing process conditions in three-dimensional systems. As such, they complement conventional characterization tools such as SEM and TEM which have their known disadvantages and limitations. In this study, we provide a thorough light scattering analysis of colloidal tungsten trioxide (WO3) nanoparticles in the shape of irregular nanospheres and cylindrical nanowires, and of the resulting aggregate morphologies. Aggregation characteristics as a function of primary particle geometry, aspect ratio of nanowires, and the change in dispersion stability in various polar solvents without the use of dispersants are monitored over different time scales and are described using the concepts of fractal theory. Using forward scattered intensities, sedimentation rates as a result of electrolyte addition and particle concentration at low solution pH are quantified, in contrast to widely reported visual observations, and are related to the aggregate structure in the dispersed phase. For nanowires of high aspect ratios, when aggregate structures cannot directly be inferred from measurements, an analytical and a quasiexperimental method are used.

Self-assembly in mixtures of an anionic and a cationic surfactant: A comparison between static light scattering and cryotransmission electron microscopy

Skoglund, Sara

January 2011

Surfactants self-assemble into aggregates above a certain concentration. In this work mixtures of the cationic surfactant cetyltrimetylammonium bromide (CTAB) and the anionic surfactant sodium octyl sulfate (SOS) were investigated systematically. The measurements were accomplished by combining the two complimentary techniques static light scattering (SLS) and cryo-transmission electron microscopy (CRYO-TEM). It was found that CTAB-rich samples contain large threadlike micelles rather close to mole fractions where vesicles start to form. The mole fraction x of the surfactant in excess in the aggregates was calculated and it was found that it differs a lot from the mole fraction in the bulk, and the transition from micelles to vesicles occurs when x is about 0.7. In the SOS-rich samples small globular micelles were observed that transform into vesicles upon dilution. Some of the samples rich in SOS were found to contain open vesicles with CRYO-TEM and the reasons for this behavior have been discussed. One question that needs to be further investigated is whether or not these structures are the result of some kind of distortion of the equilibrium process during sample preparation in connection with CRYO-TEM measurements. In most cases the two methods showed consistent results and trends, but for some samples differences could be observed.

surfactants

mixed micelles

vesicles

static light scattering

cryo-transmission electron microscopy

The Osmotic Second Virial Coefficient as a Predictor of Protein Stability

Verma, Kusum S

09 December 2006

The number of protein containing therapeutic drugs is growing day by day. Lack of proper storage conditions can cause protein degradation or aggregation. The osmotic second virial coefficient, B22, is a thermodynamic parameter, which can predict protein interaction with other proteins and solvent molecules. B22 has been successfully used as predictor of crystallization conditions for a protein in the solution, and in this study an attempt has been made to relate B22 as a predictor of stability of the protein. Static light scattering was used to measure B22 in our studies. B22 and the solubility of three proteins were measured in several excipient solutions. George et al. in 1997 related the osmotic second virial coefficient with the solubility of protein in a solution. In this study we have attempted to relate solubility with B22 and stability of lysozyme, human serum albumin, and ovalbumin in buffer solutions containing various excipients.

Static Light Scattering

Dynamic Light Scattering

Excipients

The Second Virial Coefficient

Protein Stability

Protein Solubility

Investigation of the micelle-to-vesicle transition in mixtures of an anionic and a cationic surfactant: the effect of adding salt

Leifsdotter, Josefine

January 2012

Catanoinic systems spontaneously form micelles and vesicles, which are self-assembled spherical structures made up by surfactants. In the core of the micelle a drug, or other organic substance, can be kept to stabilize it when placed in an aqueous environment. The micelle-to-vesicle transition corresponds to the moment when the drug is releases, and understanding which factors that trigger this transition is thus of great interest for the pharmaceutical industry. In this study the micelle-to-vesicle transition in water and the effect of salt were studied for the systems 95 mol% SDS/DDAB and 95 mol% SDeS/DDAB with different total concentrations. The static light scattering measurements showed that the micelle-to-vesicle transition for the system 95 mol% SDS/DDAB was shifted to lower total concentrations both when 50 mM NaBr and 100 mM NaBr were added, and that the transition was unaffected by changing the anionic surfactant from SDS to SDeS when no salt had been added. A phase separation was observed when 50 mM NaBr was added to 95 mol% SDeS/DDAB (the Krafft point was probably reached), and when 100 mM NaBr was added to the same system the sample remained opaque one week after mixing the sample and also after heating it to 40°C in a water bath. The curve for sample 95 mol% SDS/DDAB 1/8192 mM + 100 mM NaBr was oscillating implying possible defects in the vesicle membrane. The cryo-TEM images confirmed the light scattering results and additionally showed that at higher total concentrations agglomeration occurred, while whenever salt was added less vesicles seemed to appear, while both discs and broken vesicles were present suggesting that the disc structure is preferred over the spherical structure when salt is present. Also a vesicle inside another vesicle was discovered for the sample 0.95 SDS/DDAB 3.75 mM + 50 mM NaBr. The mole fraction of anionic surfactant in the aggregates (x) was calculated using a MATLAB code based on the Poisson-Boltzmann theory. The results from the calculations showed that a higher amount of SOS was needed for the system 0.95 SOS/CTAB than the amount of SDS and SDeS needed for the systems 0.95 SDS/DDAB and 0.95 SDeS/DDAB when forming aggregates, indicating that a shorter chain of the anion and the higher spontaneous curvature of the cation leads to a higher curvature. Also a larger amount of cation was needed when the tail was single than when it was double in order to form stable spherical structures. Finally, as the total concentration decreased the x value also decreased in all cases, thus the spontaneous curvature was decreased.

SDS

DDAB

NaBr

Static light scattering

cryo-TEM

drug delivery

perforated vesicles

Krafft point

Engineering and Technology

Teknik och teknologier

Estudos de interação de β2-glicoproteína I em solução aquosa e com interfaces lipídicas / Study of interaction between β2- glycoprotein I in aqueous solution and with lipid interfaces

Pozzi, Fernanda Martins

18 December 2008

A β2GPI é uma glicoproteína que circula livre ou em lipoproteínas. Adsorve em superfícies negativas, tem efeitos anticoagulantes e moduladores da inflamação. Neste trabalho caracterizou-se a interação de moléculas da proteína entre si e com superfícies lipídicas. O SDS-PAGE e o imunoblot da β2GPI identificaram monômeros, dímeros e oligômeros. Técnicas de espalhamento de luz (estático, dinâmico, Raios-X) revelaram que β2GPI forma soluções aquosas de macroagregados anisométricos. Seca sobre mica, a β2GPI forma elipsóides prolatos, observáveis por microscopia de força atômica. A forma e o tamanho das partículas dependeram de pH e concentração de proteína. A interação entre a β2GPI e superfícies lipídicas foi estudada por microgravimetria. Superfícies de fosfatidilcolina pura adsorveram β2GPI mais fracamente do que ouro ou misturas com fosfatidilserina. A adsorção de lipoproteínas artificiais à β2GPI foi dependente de pH. Sugere-se que os efeitos biológicos da β2GPI sejam mediados por interações proteína-proteína e proteína-lipídio, e dependentes de pH. / β2GPI is a blood glycoprotein circulating free or bound to lipoproteins. β2GPI adsorbs to negatively charged surfaces, acting as anticoagulant and modulator of inflammation. This work was designed to characterize the interaction between protein molecules and among protein molecules and lipid surfaces. The β2GPI SDS-PAGE and immunoblot revealed monomer, dimer and oligomers. Light scattering methods (static, dynamic and X-ray) showed that β2GPI generates aqueous solutions of anisometric macroaggregates. Atomic force microscopy showed that β2GPI dried on muscovite surfaces assembles itself in prolate ellipsoids. The particle shape and size depended both on the pH and protein concentration. The interaction among β2GPI and lipid surfaces was studied by microgravimetry. β2GPI adsorption to pure phosphatidylcholine was weaker than to gold or phosphatidylcholine/phosphatidylserine surfaces. Artificial lipoproteins adsorbed to β2GPI in a pH dependent manner. Results suggest that β2GPI biological effects could be mediated by protein-protein interactions and lipid surface binding, and pH dependent.

β2-glicoproteína I

β2-glycoproteinI

Bioquímica clínica

Dynamic light scattering

Espalhamento de luz dinâmico

Espalhamento de luz estático

Glicoproteína

Glycoprotein

Macromoléculas

Macromolecules

Static light scattering

Self assembly of surfactants and polyelectrolytes in solution and at interfaces

Bastardo Zambrano, Luis Alejandro

January 2005

This thesis focuses on the study of the interactions between polyelectrolytes and surfactants in aqueous solutions and at interfaces, as well as on the structural changes these molecules undergo due to that interaction. Small–angle neutron scattering, dynamic, and static light scattering were the main techniques used to investigate the interactions in bulk. The first type of polymer studied was a negatively charge glycoprotein (mucin); its interactions with ionic sodium alkyl sulfate surfactants and nonionic surfactants were determined. This system is of great relevance for several applications such as oral care and pharmaceutical products, since mucin is the main component of the mucus layer that protects the epithelial surfaces (e.g. oral tissues). Sodium dodecyl sulfate (SDS) on the other hand, has been used as foaming agent in tooth pastes for a very long time. In this work it is seen how SDS is very effective in dissolving the large aggregates mucin forms in solution, as well as in removing preadsorbed mucin layers from different surfaces. On the other hand, the nonionic surfactant n-dodecyl β-D-maltopyranoside (C12-mal), does not affect significantly the mucin aggregates in solution, neither does it remove mucin effectively from a negatively charge hydrophilic surface (silica). It can be suggested that nonionic surfactants (like the sugar–based C12-mal) could be used to obtain milder oral care products. The second type of systems consisted of positively charged polyelectrolytes and a negatively charged surfactant (SDS). These systems are relevant to a wide variety of applications ranging from mining and cleaning to gene delivery therapy. It was found that the interactions of these polyelectrolytes with SDS depend strongly on the polyelectrolyte structure, charge density and the solvent composition (pH, ionic strength, and so on). Large solvent isotopic effects were found in the interaction of polyethylene imine (PEI) and SDS, as well as on the interactions of this anionic surfactant and the sugar–based n-decyl β-D-glucopyranoside (C10G1). These surfactants mixtures formed similar structures in solutions to the ones formed by some of the polyelectrolytes studied, i.e. ellipsoidal micelles at low electrolyte concentration and stiff rods, at high electrolyte and SDS concentrations. / QC 20100901

Surfactant

polyelectrolyte

small–angle neutron scattering

static light scattering

dynamic light scattering

polyelectrolyte–surfactant association

protein

Surface and colloid chemistry

Yt- och kolloidkemi

Estudos de interação de β2-glicoproteína I em solução aquosa e com interfaces lipídicas / Study of interaction between β2- glycoprotein I in aqueous solution and with lipid interfaces

Fernanda Martins Pozzi

18 December 2008

A β2GPI é uma glicoproteína que circula livre ou em lipoproteínas. Adsorve em superfícies negativas, tem efeitos anticoagulantes e moduladores da inflamação. Neste trabalho caracterizou-se a interação de moléculas da proteína entre si e com superfícies lipídicas. O SDS-PAGE e o imunoblot da β2GPI identificaram monômeros, dímeros e oligômeros. Técnicas de espalhamento de luz (estático, dinâmico, Raios-X) revelaram que β2GPI forma soluções aquosas de macroagregados anisométricos. Seca sobre mica, a β2GPI forma elipsóides prolatos, observáveis por microscopia de força atômica. A forma e o tamanho das partículas dependeram de pH e concentração de proteína. A interação entre a β2GPI e superfícies lipídicas foi estudada por microgravimetria. Superfícies de fosfatidilcolina pura adsorveram β2GPI mais fracamente do que ouro ou misturas com fosfatidilserina. A adsorção de lipoproteínas artificiais à β2GPI foi dependente de pH. Sugere-se que os efeitos biológicos da β2GPI sejam mediados por interações proteína-proteína e proteína-lipídio, e dependentes de pH. / β2GPI is a blood glycoprotein circulating free or bound to lipoproteins. β2GPI adsorbs to negatively charged surfaces, acting as anticoagulant and modulator of inflammation. This work was designed to characterize the interaction between protein molecules and among protein molecules and lipid surfaces. The β2GPI SDS-PAGE and immunoblot revealed monomer, dimer and oligomers. Light scattering methods (static, dynamic and X-ray) showed that β2GPI generates aqueous solutions of anisometric macroaggregates. Atomic force microscopy showed that β2GPI dried on muscovite surfaces assembles itself in prolate ellipsoids. The particle shape and size depended both on the pH and protein concentration. The interaction among β2GPI and lipid surfaces was studied by microgravimetry. β2GPI adsorption to pure phosphatidylcholine was weaker than to gold or phosphatidylcholine/phosphatidylserine surfaces. Artificial lipoproteins adsorbed to β2GPI in a pH dependent manner. Results suggest that β2GPI biological effects could be mediated by protein-protein interactions and lipid surface binding, and pH dependent.

β2-glicoproteína I

Bioquímica clínica

Espalhamento de luz dinâmico

Espalhamento de luz estático

Glicoproteína

Macromoléculas

β2-glycoproteinI

Dynamic light scattering

Glycoprotein

Macromolecules

Static light scattering

Příprava a charakterizace komplexních nanočástic s využitím zejména frakcionace v tokovém poli a pokročilých spektroskopických metod / Preparation and Characterization of Complex Nanoparticles by Field-Flow Fractionation and Advanced Spectroscopic Methods

Kotouček, Jan

January 2020

Liposomes are versatile biocompatible and biodegradable carriers for a variety of medical applications. As the first nanoparticles, they have been approved for pharmaceutical use so far, and many liposome-based preparations are in clinical trials. Classical methods of liposome preparation represent potential limitations in technology transfer from laboratory to industrial scale. New, microfluidic techniques overcome these limitations and offer new possibilities for controlled, continuous preparation of liposomal particles in a laboratory and industrial scale. An important element in the development of new nanoparticle systems is their complex characterization and purification. In addition to the established chromatographic techniques, the Field flow fractionation technique, in particular the Asymmetrical flow Field-flow fractionation, is described. This relatively new technique in conjunction with the MALS/DLS/DAD-UV/dRI online detectors enables the purification and characterization of complex samples. The main advantage of this technique lies in the possibility of separation under native conditions, which plays an important role in the separation of biopolymers in particular. Separation in the “empty” channel then eliminates sample degradation due to unwanted interactions at the stationary phase-sample interface. The theoretical part of this thesis describes the possibilities of preparation, modification, and characterization of liposomal nanoparticles. For this purpose, optical methods based on dynamic light scattering, multi-angle dynamic light scattering and nanoparticle tracking analysis techniques are described, as well as a non-optical method using "particle by the particle" analysis, tunable resistive pulse sensing method. A separate chapter of the theoretical part is dedicated to the technique Asymmetrical flow Field-flow fractionation in connection with the above-mentioned detectors. Important results associated with this work are summarized in the attached scientific paper, together with the result summaries and the author's contributions.