20 research outputs found
Abstracts of the 7th International Conference on Lactoferrin / Résumés de la 7e Conférence internationale sur la lactoferrine
The article presents abstracts on lactoferrin research. They include "Oral administration of lactoferrin raises NK cell activity in mice,"Comparison of antimicrobial activity between lactoferricin B 15 derivative and antibiotics" and "Batch extraction of lactoferrin from raw whole milk.
Numerical Elucidation of Flow and Dispersion in Ordered Packed Beds: Non-Spherical Polygons and the Effect of Particle Overlap on Chromatographic Performance
GMA-Based Emulsion-Templated Solid Foams: Influence of Co-CrossLinker on Morphology and Mechanical Properties
Modelling Ordered Packed Beds of Spheres: The Importance of Bed Orientation and the Influence of Tortuosity on Dispersion
Effect of urea concentration on the viscosity and thermal stability of aqueous NaOH/urea cellulose solutions
Aqueous solutions of sodium hydroxide (NaOH) and urea are a known and versatile solvent for cellulose. The dissolution of cellulose occurs at subambient temperatures through the formation of a cellulose-NaOH-urea âinclusion complexâ (IC). NaOH and urea form a hydrate layer around the cellulose chains preventing chain agglomeration. Urea is known to stabilize the solution but its direct role is unknown. Using viscometry and quartz crystal microbalance with dissipation monitoring (QCM-D) it could be shown that the addition of urea reduced the solutions viscosity of the tested solutions by almost 40% and also increased the gelation temperature from approximately 40°C to 90°C. Both effects could also be observed in the presence of additional cellulose powder serving as a physical cross-linker. Using Fourier transform infrared (FTIR) spectroscopy during heating, it could be shown that a direct interaction occurs between urea and the cellulose molecules, reducing their ability to form hydrogen bonds with neighbouring chains
Flow characteristics in simulated arteries and their relationship to atherosclerosis
An experimental investigation into the link between haemodynamics and atherosclerosis is reported in this thesis. A model of a C-shaped tortuosity of the cervical portion of the human internal carotid artery (ICA) was constructed from perspex and the flow of water through the model studied by dye visualisation and Laser Doppler Anemometry (LDA), for both steady and pulsatile flow conditions. Dynamic similarity between water flow in the model and blood flow in the artery was scaled by the Reynolds number and the frequencies of unsteady flow components scaled by the Strouhal number.
Dye visualisation results are presented in a series of photographs, which illustrate the flow features in the model at given Reynolds numbers. Several differences from classical Dean-type motions in curved pipes were observed, including axial flow separation, flow asymmetry and an unexpected region of reverse flow, situated at the outer wall of the first bend in the model.
A series of axial isovel contour maps were generated from LDA measurements, for planar slices located throughout the straight sections of the tortuosity. These are presented in the form of cross-sections, normal to the pipe's central axis for steady flow conditions, for a Reynolds number of 1500. The contours show the existence of separation regions, bounded by free shear layers, which are located along the walls downstream of the inner bends. Axial isovel contour maps are also presented for planar slices near the walls of the tube, under pulsatile conditions, for a mean Reynolds number of 1500 and a flow variation of ±50% about the mean. The flow features were qualitatively similar to those seen under steady flow conditions but the intensities of the separated flows were lower during pulsatile flow than during steady flow. The separation regions were observed to move back and forth along the walls of the tube. Steady flow conditions did not allow the quantitative prediction of the locations or magnitudes of pulsatile flow features at the same instantaneous Re. Shear rates at the walls of the tube were estimated from the contours, giving an estimate of the wall shear stresses.
Regions in the model where flow separation was observed, consistently matched reported sites of proliferative atheroma in the tortuous ICA. It is concluded that regions subjected to low mean shear stresses but high fluctuating components of shear stress are associated with the proliferative lesion. Stress fluctuation fatigue of the arterial wall may play a role in initiating the proliferative lesion, by stimulating reparative processes, as suggested by Stehbens (1979). Pressure fluctuations are also implicated in the etiology of proliferative lesions. Separated shear layers in these regions are thought to be a source of pressure fluctuations, felt at the wall, especially near the reattachment position.
Regions subjected to unidirectional, high shear rates, matched reported sites of atrophic atherosclerotic lesions and sites of calcification in early atheroma. The magnitude of the shear stresses in these regions does not appear to be as important, in relation to atrophic lesions, as the presence of a unidirectional shear stress. Stress fluctuation fatigue was not indicated as the cause of degenerative changes to the wall in these regions.
A modification has been suggested of the unified hypothesis, described by Steinberg (1983), for the initiation and progression of atherosclerosis, allowing for the action of haemodynamic influences, especially in the initial stages of the disease. It has been postulated that haemodynamic factors may act in three ways: by inducing endothelial injury; by causing stress fluctuation fatigue of the blood vessel wall material; and/or by altering the transmural permeability to macromolecules, in particular low density lipoproteins.
The transendothelial transport of macromolecules, in particular Low Density Lipoproteins (LDL's), via pinocytotic vesicles was examined. An exponential factor, allowing for hindered diffusion through the vesicle neck was derived and included into Arminski et al's (1980) equation, describing the permeability of an endothelial cell. The effect of convective perturbations on the observed diffusion coefficient of LDL within the short vesicle neck was found to be negligible. A mechanism for the convective enhancement of vesicular loading is postulated, which depends crucially on the spontaneous curvature of the vesicle wall material. Convective movements through the vesicle neck may overide a geometric equilibrium concentration partitioning effect, which limits the internal vesicle LDL concentration resulting from diffusional loading, to about one third of the plasma concentration. Hence, transendothelial cholesterol transport may be increased by convective loading, in the presence of blood flow disturbances, to 3 times over that resulting from diffusional loading only
Dispersion Behavior of 3D-Printed Columns with Homogeneous Microstructures Comprising Differing Element Shapes
Reversible and Rapid pH-Regulated Self-Assembly of a Poly(ethylene glycol)âPeptide Bioconjugate
The use of external triggers to manipulate
the secondary structure
of self-assembling peptides conjugated to flexible synthetic polymers
is a challenging problem, particularly in terms of reversibility.
Here, we demonstrate, for the first time, sustained rapid and reversible,
pH-regulated self-assembly of the peptide ELELELELELF (EL-5F) and
its conjugates with 2 and 5 kDa polyÂ(ethylene glycol) (EL-5FâPEG-2K
and EL-5FâPEG-5K). Circular dichroism indicated the formation
of ÎČ-sheet structures at pH < 5.9, 5.8, and 5.4 and disassembly
to random coils above those pH values for EL-5F, EL-5FâPEG-2K,
and EL-5FâPEG-5K, respectively. ÎČ-sheets were confirmed
by the thioflavin T assay, while transmission electron microscopy
revealed the existence of extended fibrillar structures below the
above pH values. pH-induced secondary structure conversion was reproducible
for over 15 cycles, even at salt concentrations of up to 200 mM NaCl,
and was quantitatively related to the pH. Self-supporting hydrogelation
after self-assembly was observed at concentrations as low as 0.2 wt
%, which is 15-fold lower than previously reported concentrations.
This simple approach to mediate reversible self-assembly of EL-5FâPEG
bioconjugates is expected to offer novel functionality relevant to
drug delivery and bioseparation systems
Mixed Matrix Membrane Chromatography Based on Hydrophobic Interaction for Whey Protein Fractionation
The mixed matrix membrane (MMM) concept is extended, for the first time, to produce a hydrophobic interaction chromatography (HIC) membrane using crushed Phenyl Sepharoseâą (GE Healthcare Technologies, Uppsala, Sweden) resin and tested for use in whey protein fractionation. The HIC MMM had static binding capacities (membrane volume basis) of 18.419±0.605 mg mLâ1 for ÎČ-lactoglobulin, 45.850±2.753 mg mLâ1 for α-lactalbumin, 41.106±9.004 mg mLâ1 for bovine serum albumin and 42.467±4.130 mg mLâ1 for lactoferin in individual protein solutions. For flowthrough whey fractionation, the adsorption performance of the HIC MMM was similar to a HiTrapâą Phenyl (GE Healthcare Technologies) HIC column. However, the well-known high processing speeds and inherently low pressure drops of MMM chromatography may offer benefits over a conventional packed bed column