Jörg Teßmar

Biodegradable poly(d,l-lactic acid)-poly(ethylene glycol)-monomethyl ether diblock copolymers: structures and surface properties relevant to their use as biomaterials

To obtain biodegradable polymers with variable surface properties for tissue culture applications, poly(ethylene glycol) blocks were attached to poly(lactic acid) blocks in a variety of combinations. The resulting poly(D,L-lactic acid)-poly(ethylene glycol)-monomethyl ether (Me.PEG-PLA) diblock copolymers were subject to comprehensive investigations concerning their bulk microstructure and surface properties to evaluate their suitability for drug delivery applications as well as for the manufacture of scaffolds in tissue engineering. Results obtained from 1H-NMR, gel permeation chromatography, wide angle X-ray diffraction and modulated differential scanning calorimetry revealed that the polymer bulk microstructure contains poly(ethylene glycol)-monomethyl ether (Me.PEG) domains segregated from poly(D,L-lactic acid) (PLA) domains varying with the composition of the diblock copolymers. Analysis of the surface of polymer films with atomic force microscopy and X-ray photoelectron spectroscopy indicated that there is a variable amount of Me.PEG chains present on the polymer surface, depending on the polymer composition. It could be shown that the presence of Me.PEG chains in the polymer surface had a suppressive effect on the adsorption of two model peptides (salmon calcitonin and human atrial natriuretic peptide). The possibility to modify polymer bulk microstructure as well as surface properties by variation of the copolymer composition is a prerequisite for their efficient use in the fields of drug delivery and tissue engineering.

Hydrogel-based drug delivery systems: Comparison of drug diffusivity and release kinetics

Hydrogels are extensively studied as matrices for the controlled release of macromolecules. To evaluate the mobility of embedded molecules, these drug delivery systems are usually characterized by release studies. However, these experiments are time-consuming and their reliability is often poor. In this study, gels were prepared by step-growth polymerization of poly(ethylene glycol) (PEG) and loaded with fluoresceine isothiocyanate (FITC) labeled dextrans. Mechanical testing and swelling studies allowed prediction of the expected FITC-dextran diffusivity. The translational diffusion coefficients (D) of the incorporated FITC-dextrans were measured by fluorescence recovery after photobleaching (FRAP) and pulsed field gradient NMR spectroscopy. Because the determined values of D agreed well with those obtained from release studies, mechanical testing, FRAP, and pulsed field gradient NMR spectroscopy are proposed as alternatives to release experiments. The applied methods complemented each other and represented the relative differences between the tested samples correctly. Measuring D can therefore be used to rapidly evaluate the potential of newly developed drug delivery systems.

Enzymatically degradable poly(ethylene glycol) based hydrogels for adipose tissue engineering

Adipose tissue engineering requires biomaterials that promote the differentiation of seeded adipocytes. Here, we report on the development and characterization of in situ forming, poly(ethylene glycol) (PEG) based hydrogels for soft tissue augmentation. Branched PEG-amines were modified with collagenase-sensitive peptides and cross-linked with branched PEG-succinimidyl propionates without the use of free-radical initiators (enzymatically degradable hydrogels). Alanine-modified PEG-amines were used for the preparation of non-degradable gels. Depending on the used polymer concentration, the strength of degradable gels after swelling ranged from 1708 to 7412 Pa; the strength of non-degradable hydrogels varied between 1496 and 7686 Pa. Enzyme mediated gel degradation occurred within 10, 16, and 19 days (5%, 10%, and 15% initial polymer content). To evaluate their suitability as scaffold materials for adipose tissue engineering, the hydrogels were functionalized with the laminin-derived adhesion peptide YIGSR, and seeded with 3T3-L1 preadipocytes. Compared to a standard two-dimensional cell culture model, the developed hydrogels significantly enhanced the intracellular triglyceride accumulation of encapsulated adipocytes. Functionalization with YIGSR further enhanced lipid synthesis within differentiating adipocytes. Long-term studies suggested that enzymatically degradable hydrogels furthermore promote the formation of coherent adipose tissue-like structures featuring many mature unilocular fat cells.

The effect of poly(ethylene glycol)–poly(d,l-lactic acid) diblock copolymers on peptide acylation

The combination of poly(ethylene glycol) (PEG) with a biodegradable poly(ester), such as poly(D,L-lactic acid) (PLA), is an approach that has been successfully used for the stabilization of proteins and peptides in several biodegradable delivery devices. The acylation of peptides inside degrading PLA microspheres has been described only recently as another instability mechanism related to the accumulation of polymer degradation products inside eroding PLA. We investigated whether the block copolymerization of PLA with PEG reduces peptide acylation inside degrading microspheres. Diblock copolymers consisting of poly(D,L-lactic acid) covalently bound to poly(ethylene glycol)-monomethyl ether (Me.PEG-PLA) were used for these investigations. Human atrial natriuretic peptide (ANP) was incorporated into microspheres manufactured from Me.PEG5-PLA45, a diblock copolymer with an overall PEG content of 10%. Peptide integrity inside the microspheres was monitored by HPLC-MS analysis during 4 weeks of microsphere degradation in isotonic phosphate buffer (pH 7.4) at 37 degrees C. Inside the degrading Me.PEG5-PLA45 microspheres, acylation products as well as an oxidation product of ANP were formed. The results demonstrate that the combination of PEG with PLA does not necessarily display a favorable effect concerning peptide acylation inside degrading polymer microspheres. However, they also suggested that the acylation reaction is mainly driven by the formation and accumulation of polymer degradation products inside the degrading microspheres.

Hydrogels for Tissue Engineering

Today’s tissue engineering approaches rely on two different types of polymeric cell carriers. First, there are the well-established solid scaffolds, such as poly(α-hydroxy esters), which are generally based on lipophilic but hydrolytically degradable polymers that were originally designed as degradable sutures or drug-releasing matrix materials. Alternatively, new and promising strategies rely on hydrophilic polymer networks; these are based on hydrogels, which are also degradable polymers. Hydrophilic polymer network systems are suitable for many of the soft tissue engineering applications that do not require the strong mechanical support of solid scaffolds, but rather a flexible material that mimics the extracellular matrix (ECM). Highly hydrated hydrophilic polymer networks contain pores and void space between the polymer chains (Fig. 37.1); this provides many advantages over the common solid scaffold materials, including an enhanced supply of nutrients and oxygen for the cells. Pores within the network provide room for cells, and after proliferation and expansion, for the newly formed tissue. Their formation can be controlled using chemical modifications of the hydrogel network.

FACS as useful tool to study distinct hyalocyte populations

Hyalocytes, the cells of the vitreous body, are assumed to be involved in physiological as well as patho-physiological processes within the eye. However, current knowledge about the cells is still limited. As different morphological types of hyalocytes are described in the literature, it seems reasonable to try to isolate individual populations prior to characterization of single cell types. To achieve this, the present study investigated the utility of fluorescence activated cell sorting (FACS) for hyalocyte separation. Subsequent to digestion of vitreous bodies using collagenase, the resulting cell suspension was analyzed and separated using FACS without any additional staining. Two-parameter dot plots of forward scatter (indicating size) against sideward scatter (indicating granularity) showed two distinct cell populations; staining with propidium iodide confirmed that both populations represent living cells. After sorting, cells of both populations were seeded on tissue culture plastic (tissue culture treated polystyrene). Only one population attached and proliferated, whereas the other population was non-adherent. Even when seeding the native cell mix, only one population of cells was observed after two passages, as indicated by FACS. Furthermore, ascorbic acid increased proliferation of these cells similarly to the proliferation of the separated cell population. These data point out that only one of the two populations adheres and proliferates on tissue culture plastic. To conclude, the established isolation technique allows for separation of clearly defined hyalocyte populations. Moreover, clear hints were obtained that only one of the two populations adheres and proliferates under the commonly applied culture conditions.

Nanoparticulate detection systems for the evaluation of New Drug Delivery Approaches and Drug Targeting principles

In order to provide nanoparticulate detection systems for the evaluation of drug delivery approaches, two complementary particle types were optimized with respect to their physical and chemical properties. Hydrophilic coated quantum dots and colloidal gold nanoparticles were established as platforms for the investigation of drug targeting and nanoparticle diffusion. By optimizing the synthesis towards longer emission wavelengths the quantum dots will become suitable for near IR in vivo imaging and the synthesized coating polymers for the gold particles furthermore provided an excellent in vitro stability, which was demonstrated in an in-vivo experiment. Both systems proved to be valuable partners for the design of new drug delivery formulations.