Wolfgang Albrecht

Formation of hollow fiber membranes from poly(ether imide) at wet phase inversion using binary mixtures of solvents for the preparation of the dope

Abstract Macrovoidal morphologies are commonly generated when forming membranes by immersion precipitation at an instantaneous phase demixing. In this investigation, hollow fiber membranes from poly(ether imide) were prepared using instantaneous phase separation in dependence on the dope solvent composition allowing a defined and wide variation of the thermodynamical state of the spinning solution from a good to a metastable state. The results show that by a systematic variation of the dope solvent composition, the morphology of the membranes can be varied from macrovoidal to sponge-like structures despite instantaneous phase demixing. Two locations were observed at which the macrovoids were started. First beneath the primary coagulation front (type 1) and second far away of the primary coagulation front in the cross-section (type 2). The first type could correlate to the cloud points and is preferable induced by the thermodynamic state of the dope. Basing on the kinetic data here reported it was hypothesized that the second type starting far away from the primary coagulation layer is preferable induced by the kinetics of the phase inversion.

Membranes for biohybrid liver support systems--investigations on hepatocyte attachment, morphology and growth.

The biological properties of four different membranes were studied regarding their possible application in biohybrid liver support systems. Two of them, one made of polyetherimide (PEI), and a second based on polyacrylonitrile-N-vinylpyrollidone co-polymer (P(AN-NVP)), were recently developed in our lab and studied for the first time. Together with pure polyacrylonitrile (PAN) membranes, the three preparations were characterised as ultra-filtration membranes. Their ability to support cell attachment, morphology, proliferation and function of human hepatoblastoma C3A cells was studied. The role of surface morphology for the interaction with hepatocytes was highlighted using a commercial, moderately wettable polyvinylidendifluoride (PVDF) membrane with micro-filtration properties. Comparative investigations showed strongest interaction of C3A cells with PAN membranes, as the focal adhesion contacts were more expressed and cell growth was also high. However, the functional activity in terms of albumin synthesis was reduced. Very similar results were obtained with the most hydrophobic PEI membrane. In contrast, the most hydrophilic membrane P(AN-NVP) was found to provoke stronger homotypic adhesion (E-cadherin expression) of C3A cells and less substratum attachment (focal adhesions), but enhanced albumin secretion. However, proliferation of C3A cells was lowered. Micro-porous PVDF membrane showed very good initial attachment, but the resulting cell material and cell-cell interaction were relatively poor developed. Among four membranes tested, PEI seems to be the most attractive membrane for biohybrid liver devices, as it provides good surface properties for hepatocytes interaction, but in addition it is highly thermostable, which would permit steam sterilisation. No simple relationship, however, between the wettability of the membranes and their ability to support hepatocyte adhesion and function was found in this study.

Functionalized nanoparticles for endotoxin binding in aqueous solutions

Nanoparticles consisting of a polystyrene core and a polyglycidyl methacrylate shell were prepared by a two-step emulsion polymerization. The size and surface properties of the particles were characterized by scanning electron microscopy, dynamic light scattering and polyelectrolyte titration techniques. Particles were found to be monodisperse with a mean diameter of about 85 nm. Parent particles were modified with a number of different ligands including diamines of increasing chain length, amino acids and corresponding amines and higher molecular weight ligands like polymyxin B. The modified particles were tested for their endotoxin (ET) binding capacity in water and physiological sodium chloride solution with the Limulus amebocyte lysate (LAL) assay. It was found that the ET binding properties of the different ligands depend both on the ability of the ligand to form Coulomb- and van der Waals-interactions with the ET molecule influenced by the nature of the suspension medium. Therefore, the choice of ligands for particle modification has to consider minutely the conditions under which ET has to be removed, e.g. removal from pure water, dialysis fluids, plasma or blood.

MORPHOLOGICAL EVIDENCE FOR A DIFFERENT FIBRONECTIN RECEPTOR ORGANIZATION AND FUNCTION DURING FIBROBLAST ADHESION ON HYDROPHILIC AND HYDROPHOBIC GLASS SUBSTRATA

A polyclonal antibody against the beta 1 subunit of the fibronectin (FN) receptor was used to mimic the early events of integrin receptor functioning to study the initial cellular processes during the organization of FN matrix on biomaterials. Hydrophilic glass and hydrophobic octadecylsilane (ODS) surfaces have been applied as models for different biocompatible materials. By immunofluorescence we could demonstrate that FN receptors organize on the dorsal cell surface of adhering fibroblasts in a specific linear pattern along with actin filaments, but only if the cells were attached to hydrophilic glass. In contrast, FN receptors were not reorganized on hydrophobic octadecylsilane (ODS). In parallel experiments, FN matrix formation after 72 h of incubation on the same substrata has been analyzed microscopically, and quantified by cell ELISA, in order to be further correlated with the integrin receptor functioning in contact with the biomaterials. It was found that FN structuring and the amount of FN matrix have been significantly diminished on ODS that was related to the observed changes in integrin receptor functioning. To learn more about the mechanism of this phenomenon, desorption of 125I-FN from these substrata was studied and found to be significantly decreased on hydrophobic ODS. As a consequence, FN receptor (function) might be arrested on the ventral cell surface, thus the important role of beta 1 integrins in the positional organization of the FN matrix may be disturbed. In light of these facts, antibody-induced clustering of FN receptor can be considered as a useful model for studying the early steps of FN matrix formation on biomaterials.

Fibrinogen adsorption and platelet interactions on polymer membranes

The hemocompatibility of four different wettable polymer membranes, namely Cuprophan (CE), polyether-polycarbonate (PC-PE), polysulfone (PSU), and polyetherimide (PEI), was investigated with respect to flbrinogen (Fng) adsorption and platelet adhesion/activation. In order to estimate the polar and dispersion components of the surface free energy, contact angles using water/vapor and water/n-hexadecane systems were measured. Adsorption of flbrinogen was studied using fluorescence-labeled protein. The adsorption isotherms showed that the amount and the affinity of adsorbed Fng increased with decreasing surface wettability of the membranes, which correlates with the dispersion and polar components of the surface free energy. The conformational changes of adsorbed Fng were detected by measuring the difference between monoclonal antibody binding to the conformation-sensitive epitope in the D-domain and the binding of polyclonal anti-Fng antibody. The anticipated conformational/orientational changes were greater for PEI and PSU membranes (the least wettable membranes) and negligible for the more wettable PC-PE and CE membranes. In addition, a possible relationship with the degree of platelet activation was found, showing negligible platelet adhesion on PC-PE and CE, but high platelet adhesion on PEI and PSU. Furthermore, platelets were spread to a large extent on PEI, while the formation of aggregates was observed on PSU. This may correspond to the anticipated differences in the conformational state of Fng on both membranes.

A novel technique for preparation of aminated polyimide membranes with microfiltration characteristics

In the wet-chemical treatment of polyimide (PI) membranes with aminic modifiers, the modifier molecules will be covalently bound to the membrane polymer. Using modifiers with high aminic nitrogen the amination is combined with a degradation process, which shifts separation properties from ultrafiltration characteristics (untreated membrane) to microfiltration characteristics (treated membrane). Under optimal treatment conditions the steepness of separating curves of the aminated membranes is comparable with the steepness of separating curves of commercial microfilters. Characteristic data of membranes such as water permeability, amine content, SEM morphology, wettability and the dependence of membrane thickness on treatment conditions were presented. Data show that membrane properties are insensitive to modifier concentration in the treatment bath with respect to degradation reaction but sensitive to reaction rate. From the data of amine content per unit surface area of membrane and amine content per unit membrane weight, it was concluded that the functionalization/degradation process is divided in two steps. In the first step functionalization dominates, whereas in the second step functionalization and degradation are simultaneous processes resulting in an equilibrium state. The expected reaction sequence of degradable functionalization is proposed and discussed. Initial membrane morphology seems to be the key parameter for further investigations to optimize membrane preparation processes.

Altered vitronectin receptor (αv integrin) function in fibroblasts adhering on hydrophobic glass

Function of integrins is crucial for adhesion, movement, proliferation, and survival of cells. In a recent study we found impaired fibronectin receptor function on hydrophobic substrata (G. Altankov et al. J Biomater Sci Polym Edn 1997;8:712-740). Here, we have studied the distribution and function of the vitronectin receptor (alphav integrin) in fibroblasts adhering on hydrophilic glass and hydrophobic octadecyl glass (ODS). The morphology of fibroblasts and the organization of actin cytoskeleton were studied and found to be altered on ODS, where the cells did not spread and possessed condensed actin. Pretreatment of the surfaces with serum or pure vitronectin improved cell morphology on both substrata, resulting in the development of longitudinal actin stress fibers. It was found with biotinylated vitronectin that comparable quantities of vitronectin were adsorbed from single vitronectin solutions or serum on glass and on hydrophobic ODS. The organization of the vitronectin receptors on the ventral cell surface was investigated in permeabilized cells showing normal focal adhesions in fibroblasts plated on glass but none of these structures on ODS. The distribution of alphav integrin on the dorsal cell surface was studied on nonpermeabilized living cells after antibody tagging. While fibroblasts adhering on plain or serum-treated glass developed a linear organization of alphav integrin, cells on plain and serum-treated ODS were not able to reorganize the vitronectin receptor. Studies on signal transduction with antiphosphotyrosine antibodies revealed co-localization of alphav integrin and phosphotyrosine in focal adhesions on glass and serum-treated glass. However, signaling was almost absent on plain ODS and weak on serum-treated ODS. It was concluded that alterations in vitronectin receptor function on the ventral cell surface caused by the hydrophobic material surface inhibit signal transfer and subsequent intracellular events that are important for the organization and function of integrins.

Hemocompatibility of poly(ether imide) membranes functionalized with carboxylic groups

Materials for blood-contacting applications have to meet high requirements in terms to prevent thrombotic complications after the medical treatment. Surface induced thrombosis, e.g., after application of cardiovascular devices, is linked clearly to the activation of coagulation system and platelet adhesion and activation. The flat sheet poly(ether imide) membrane (PEI) was modified by binding of iminodiacetic acid (IDA) for different periods of time to obtain surfaces with carboxylic (–COOH) groups, namely PEI-1 (modified for 1xa0min) and PEI-2 (modified for 30xa0min). The successful binding of the ligands was monitored by thionin acetate assay. The physico-chemical characteristics of the materials were analyzed by SEM, AFM, water contact angle, and Zeta potential measurements. Hemocompatibility of the polymer materials was studied by analyzing the activation of coagulation system (plasma kallikrein-like activity) and platelet adhesion/activation by using immunofluorescence technique. The blood response to PEI membranes was compared to that of a commercial poly(ethylene terephthalate) (PET) membrane. Our results showed that the increase of the negative charges on the modified PEI membrane surfaces (number of –COOH groups) caused a higher contact activation of the coagulation system and a higher rate of platelet adhesion and activation compared to non-modified PEI. However, overall the hemocompatibility of all PEI membranes was higher than that of PET.

Contact activation of plasmatic coagulation on polymeric membranes measured by the activity of kallikrein in heparinized plasma

Kallikrein is involved in the generation of bradykinin during extracorporal circulation, that is believed to play an important role in cases of anaphylactic shock during hemodialysis. Therefore, a method for the assessment of kallikrein generation was developed, based on the chromogenic substrate S-2302. Comparison of kallikrein-like activity on glass using citrate or heparinized plasma demonstrated enhanced activity in the presence of heparin. The applicability of the assay, and the time course of kallikrein generation was demonstrated with glass and cuprophan. Membranes based on pure polyacrylonitrile, or its copolymers differing in their content of acrylic acid, 2-hydroxyethyl acrylate, and allylsulphonate were investigated with respect to kallikrein-like activity, and physicochemical surface properties. It was found that high content in 2-hydroxyethyl acrylate, and acrylic acid caused a substantial activation of the contact system while low content in allylsulphonate (less than 2 mol%) did not result in enhanced kallikrein-like activity. The activating materials were characterized to be highly wettable, and had the most negative zeta potentials.

Poly(ether imide) membranes: studies on the effect of surface modification and protein pre-adsorption on endothelial cell adhesion, growth and function.

Poly(ether imide) (PEI) membranes of which the surface was modified with carboxylic groups were tested in comparison to pure PEI and poly(ethylene terephtalate) (PET) for their ability to support attachment, growth and function of human umbilical vein endothelial cells (HUVEC) with respect to endothelization of the above materials. Flat sheet PEI membranes were modified by covalent binding of iminodiacetic acid (IDA) for different periods of time (1 to 30 min) to obtain surfaces with various content of carboxylic groups. In addition, fibronectin (FN) and fibrinogen (FNG) pre-adsorption on the various membranes were studied for their effect on HUVEC behaviour. The results show a decreased protein adsorption and HUVEC adhesion, growth and function in terms of prostacyclin production with an increase in carboxylic groups. Pre-adsorption of the membranes with FN or FNG promoted activity of HUVEC, which became superior to cells on PET. FN-coated membranes were found to be a better substrate for HUVEC adhesion and prostacyclin production, while on FNG-coated membranes cells grew better. Overall it can be concluded that PEI is a promising materials for endothelial cells immobilization as it is needed for improving the haemocompatibility of cardiovascular devices.