Synthesis and characterization of aliphatic hyperbranched polyesters

Vuković, Jasna

22 November 2006

Two series of aliphatic hyperbranched (HB) polyesters have been synthesized from 2,2-bis(hydroxymethyl)propionic acid and di-trimethylolpropane using pseudo-one-step or one-step procedure. The structure and properties of these HB polyesters, investigated with different characterization techniques in solution, melt and solid state, were compared between each other, with commercial Boltorn HB polyesters and samples obtained by modification of the end -OH groups with ß-alanine or stearic acid. Seven HB polyesters were fractionated in order to obtain three fractions of each sample. The experimental results obtained from NMR spectroscopy, acid and hydroxyl number titration, GPC, vapour pressure osmometry, MALDI TOF and ESI mass spectrometry indicate that during the synthesis reactivity of terminal and linear -OH groups was not the same and that side reactions occurred in significant amount, which led to the lowering of the number average molar mass and broadening of the molar mass distribution. According to the results obtained from viscosimetry of diluted solutions and dynamic light scattering the best solvents for these HB polyesters are 0.7 mass % solution of LiCl in N,N-dimethylacetamide and N-methyl-2-pyrrolidinon (NMP). The limiting viscosity number and the hydrodynamic radius of the samples increase up to the sixth pseudo generation in these two solvents. Investigated HB polyesters behave as Newtonian liquids in concentrated solutions (c < 50 mass % in NMP) at T < 55 °C. The same was observed for the samples from fourth till sixth pseudo generation in melt at T > 70 °C. At all other experimental conditions used in this work these polymers show shear-thinning behaviour due to the high ability for the aggregation. Thermal stability of investigated HB polyesters increases with increasing number of the pseudo generation. The influence of the procedure for the synthesis and type of end groups on the properties of these polymers is discussed.

Hyperbranched polyesters

molar mass determination

hydrodynamic radius

diluted solution properties

rheology

thermal stability

synthesis

30 - Chemie

ddc:660

Evaluating the inter and intra batch variability of protein aggregation behaviour using Taylor dispersion analysis and dynamic light scattering

Hulse, W.L., Gray, J., Forbes, Robert T.

January 2013

No / Biosimilar pharmaceuticals are complex biological molecules that have similar physicochemical properties to the originator therapeutic protein. They are produced by complex multi-stage processes and are not truly equivalent. Therefore, for a biosimilar to be approved for market it is important to demonstrate that the biological product is highly similar to a reference product. This includes its primary and higher order structures and its aggregation behaviour. Representative lots of both the proposed biosimilar and the reference product are analysed to understand the lot-to-lot variability of both drug substances in the manufacturing processes. Whilst it is not easy to characterise every variation of a protein structure at present additional analytical technologies need to be utilised to ensure the safety and efficacy of any potential biosimilar product. We have explored the use of Taylor dispersion analysis (TDA) to analyse such batch to batch variations in the model protein, bovine serum albumin (BSA) and compared the results to that obtained by conventional dynamic light scattering analysis (DLS). Inter and intra batch differences were evident in all grades of BSA analysed. However, the reproducibility of the TDA measurements, enabled the stability and reversibility of BSA aggregates to be more readily monitored. This demonstrates that Taylor dispersion analysis is a very sensitive technique to study higher order protein states and aggregation. The results, here, also indicate a correlation between protein purity and the physical behaviour of the samples after heat shocking. Here, the protein with the highest quoted purity resulted in a reduced increase in the measured hydrodynamic radius after heat stressing, indicating that less unfolding/aggregation had occurred. Whilst DLS was also able to observe the presence of aggregates, its bias towards larger aggregates indicated a much larger increase in hydrodynamic radii and is less sensitive to small changes in hydrodynamic radii. TDA was also able to identify low levels of larger aggregates that were not observed by DLS. Therefore, given the potential for immunogenicity effects that may result from such aggregates it is suggested that TDA may be suitable in the evaluating detailed batch to batch variability and process induced physical changes of biopharmaceuticals and biosimilars.

Chemistry techniques

; Light

; Proteins

; Scattering

; Serum albumin

; Aggregation

; Biosimilar

; Dynamic light scattering

; Hydrodynamic radius

; Taylor dispersion analysis

Molecular Sizing using Fluorescence Correlation Spectroscopy / Molecular Sizing using Fluorescence Correlation Spectroscopy

Loman, Anastasia

29 June 2010

No description available.

530 Physik

absoluter Diffusionskoeffizient

Translations-Diffusion

Rotations-Diffusion

Hydrodynamischer Radius

absolute diffusion coefficient value

translational diffusion

rotational diffusion

hydrodynamic radius

33.07

42.12

RR

WC

Nanoscale Brownian Dynamics of Semiflexible Biopolymers

Mühle, Steffen

16 July 2020

No description available.

571.4

complex systems

polymer dynamics

brownian motion

elasticity

differential geometry

single-molecule experiment

single-molecule experiments

biophysics

fluorescence correlation spectroscopy

loop formation

translational diffusion

stochastic dynamics

thermal equilibrium

overdamped hydrodynamics

conformational dynamics

protein dynamics

protein folding

loop closure kinetics

intrinsically disordered protein

PET-FCS

2fFCS

hydrodynamic radius

Biologie (PPN619462639)