Effect of polymerization conditions on the network properties of dex-HEMA microspheres and macro-hydrogels

Dextran-hydroxy-ethyl-methacrylate (dex-HEMA) hydrogels in the form of microspheres are an attractive system for the controlled delivery of protein drugs. In this work, the microspheres were prepared by a water-in-water emulsion polymerization process. The polymerization reaction was initiated by potassium peroxodisulfate (KPS) and catalyzed by N,N,N',N'-tetramethylethylenediamine (TEMED). The effect of the initiator concentration, reaction temperature and pH on the mechanical and network properties of the microspheres were investigated. The size and size distribution of the microspheres, equilibrium water content, and methacrylate conversion were also determined. The mechanical properties of single microspheres were measured by a micromanipulation technique and the rheological characteristics of the same material in the form of macroscopic hydrogel slabs were determined by a controlled stress rheometer. The results showed that the Young's moduli of the microspheres and of macroscopic slabs measured by these two methods were in good agreement. Higher KPS initiator concentrations resulted in a more rapid polymerization with a shorter gelation and lag time, and a higher Young's modulus of the gels. An increase in temperature also resulted in a more rapid polymerization with a shorter gelation and lag time. However, the Young's modulus of the gels decreased with an increase in polymerization temperature. The pH had no significant effect on the mechanical properties of the microspheres. This study demonstrates that the network properties of dex-HEMA hydrogels can be tailored by the polymerization conditions, which opens the possibility to modulate the release rate of entrapped compounds.

Biodegradable dextran hydrogels crosslinked by stereocomplex formation for the controlled release of pharmaceutical proteins

Hydrogels are based on hydrophilic polymers, which are crosslinked to prevent dissolution in water. Because hydrogels can contain large amounts of water, they are interesting devices for the delivery of proteins. In this contribution a biodegradable dextran hydrogel is described which is based on physical interactions and is particularly suitable for the controlled delivery of pharmaceutically active proteins. The unique feature of our system is that the preparation of the hydrogels takes place in an all-aqueous solution, by which the use of organic solvents is avoided. Furthermore, chemical crosslinking agents are not needed to create the hydrogels, since crosslinking is established physically by stereocomplex formation between enantiomeric oligomeric lactic acid chains. The hydrogel is simply obtained after mixing aqueous solutions of dextran(l)-lactate and dextran(d)-lactate. In this contribution, the formation of the hydrogels as well as their protein release properties and degradation behavior are discussed.

The effect of the processing and formulation parameters on the size of nanoparticles based on block copolymers of poly(ethylene glycol) and poly(N-isopropylacrylamide) with and without hydrolytically sensitive groups

Block copolymers of poly(ethylene glycol) (PEG) as a hydrophilic block and N-isopropylacrylamide (PNIPAAm) or poly (NIPAAm-co-N-(2-hydroxypropyl) methacrylamide-dilactate) (poly(NIPAAm-co-HPMAm-dilactate)) as a thermosensitive block, are able to self-assemble in water into nanoparticles above the cloud point (CP) of the thermosensitive block. The influence of processing and the formulation parameters on the size of the nanoparticles was studied using dynamic light scattering. PNIPAAm-b-PEG 2000 polymers were not suitable for the formation of small and stable particles. Block copolymers with PEG 5000 and 10000 formed relatively small and stable particles in aqueous solutions at temperatures above the CP of the thermosensitive block. Their size decreased with increasing molecular weight of the thermosensitive block, decreasing polymer concentration and using water instead of phosphate buffered saline as solvent. Extrusion and ultrasonication were inefficient methods to size down the polymeric nanoparticles. The heating rate of the polymer solutions was a dominant factor for the size of the nanoparticles. When an aqueous polymer solution was slowly heated through the CP, rather large particles (> or = 200 nm) were formed. Regardless the polymer composition, small nanoparticles (50-70 nm) with a narrow size distribution were formed, when a small volume of an aqueous polymer solution below the CP was added to a large volume of heated water. In this way the thermosensitive block copolymers rapidly pass their CP ('heat shock' procedure), resulting in small and stable nanoparticles.

Steric stabilization of poly(2-(dimethylamino)ethyl methacrylate)-based polyplexes mediates prolonged circulation and tumor targeting in mice

BACKGROUND

Efficient tumor targeting of polymeric gene transfer systems (polyplexes) represents a major challenge. To establish tumor targeting after intravenous (IV) administration, the circulation lifetime of these systems should be sufficiently long. Since naked polyplexes are rapidly eliminated from the circulation after IV adminstration, strategies have to be developed to improve their pharmacokinetics.

METHODS

Complexes of plasmid DNA and poly(2-(dimethylamino)ethyl methacrylate) (pDMAEMA)-graft-PEG or AB di-block copolymers of pDMAEMA and PEG, as well as PEGylated complexes prepared via PEGylation of preformed complexes (postPEGylation), were evaluated for their physicochemical properties (size and charge) their interactions with blood constituents and transfection activity in vitro. The pharmacokinetics and biodistribution of PEG-polyplexes were studied in mice after IV administration. The degree of accumulation in two subcutaneous (SC) mouse tumors after IV administration was evaluated for the system with the longest circulation time.

RESULTS

It is shown that the surface charge of the pDMAEMA-polyplexes was effectively shielded by two PEGylation methods (i.e. the use of pDMAEMA-graft-PEG polymers and postPEGylation). The shielding effect was the highest for the postPEGylation method with PEG(20000), yielding polyplexes that hardly show interactions with blood components (i.e. albumin and erythrocytes) and show substantially prolonged circulation time in mice after IV administration. The superior colloidal stability and circulation kinetics of the postPEGylated polyplexes translated into tumor accumulation which amounted to about 3.5% of the injected dose per gram tumor tissue in a SC Neuro2A tumor model and to about 4.2% of the injected dose per gram tumor tissue in a SC C26 tumor model.

CONCLUSIONS

This study shows that postPEGylation of pDMAEMA-based polyplexes is the most attractive method to prepare polyplexes with long circulating properties. Tumor targeting capacity after intravenous administration was demonstrated in two subcutaneous tumor models.

IL-2 loaded dextran microspheres with attractive histocompatibility properties for local IL-2 cancer therapy

Biodegradable dextran microspheres (MS) were developed as a slow-release system for interleukin-2 (IL-2) to apply them for local IL-2 therapy of cancer. We describe the tissue reactions induced by these MS without or with IL-2 in rats. Dextran MS stain bright red-purple with the periodic acid Schiff (PAS), visualising the exact spot of IL-2 release and its relation to the histological reaction pattern. Subcutaneously injected MS always form a well-circumscribed deposit. In the first 2 days there is a PMN inflammation within the MS-deposit, but the surroundings show only a scanty inflammatory reaction. The PMN reaction is replaced by an abundant macrophage reaction in particular in the MS-deposit. At day 21 a fibrous capsule of about 50 mum surrounds the deposit. The effect of IL-2 administered in its free form is mainly vascular, with vascular dilatation, vascular leakage and oedema. It is remarkable that lymphocytes are present in the injection area already at day 2. When IL-2 releasing MS were used, the various reactions induced by IL-2 and MS were amplified leading to local necrosis. We conclude that neither placebo MS nor IL-2 leads to necrosis after subcutaneous injection in rats. In contrast, when IL-2 was released from MS, then massive necrosis was induced. This might be due to increased phagocytosis or changes in the micro-niche due to the release of humoral factors by the infiltrating cells. This is probably fortuitous for local IL-2 therapy of cancer, as massive necrosis of tumour cells can be expected to lead to an increased antitumour reaction.

Water-soluble biodegradable cationic polyphosphazenes for gene delivery

Polyphosphazenes bearing cationic moieties were synthesized from poly(dichloro)phosphazene, which in turn was obtained by thermal polymerization of hexachlorocyclotriphosphazene in 1,2,4-trichlorobenzene. Next, either 2-dimethylaminoethanol (DMAE) or 2-dimethylaminoethylamine (DMAEA) side groups were introduced by a substitution reaction. The polymers were purified by dialysis against water and tetrahydrofuran, lyophilized and evaluated as polymeric transfectants. The polyphosphazenes were able to bind plasmid DNA yielding positively charged particles (polyplexes) with a size around 80 nm at a polymer/DNA ratio of 3:1 (w/w). The polyphosphazene-based polyplexes were able to transfect COS-7 cells in vitro with an efficiency comparable to a well-known polymeric transfectant [poly(2-dimethylaminoethyl methacrylate), pDMAEMA]. The toxicity of both polyphosphazenes was lower than pDMAEMA. The transfection efficiency for the poly(DMAE)phosphazene-based polyplexes was about threefold higher in the absence of serum than in the presence of 5.0% fetal bovine serum. This is probably caused by unfavorable interactions of the polyplexes with serum proteins. In contrast, the poly(DMAEA)phosphazene-based polyplexes showed a threefold lower transfection activity in the absence of serum. For this system, serum proteins likely masked the toxicity of the polyplexes, as shown by the XTT cell viability assay and confocal laser scanning microscopy studies. Preliminary degradation studies indicate that the polymers were indeed degradable. The half-life at pH 7.5 and 37 degrees C was around 7 days for poly(DMAE)phosphazenes and 24 days for poly(DMAEA)phosphazenes. This study shows that polyphosphazenes are a suitable and promising new class of biodegradable polymeric carriers for gene delivery.

Preparation and characterization of folate-targeted pEG-coated pDMAEMA-based polyplexes

A folate-poly(ethylene glycol) conjugate capable of covalent coupling to primary amines present at the surface of polyplexes was developed. Coating of poly(dimethylaminomethyl methacrylate (pDMAEMA)-based polyplexes with this folate-pEG conjugate led to a sharp decrease of the zeta-potential, and a small increase in particle size. The size of the particles in isotonic medium did not change markedly in time demonstrating that rather stable particles were formed. The in vitro cellular toxicity of the pEGylated polyplexes with and without folate ligands was lowered considerably compared to uncoated polyplexes. The toxicity observed for the targeted pEGylated polyplexes was slightly higher than that of corresponding untargeted polyplexes, which might indicate an increased cellular association of targeted polyplexes. Transfection of OVCAR-3 cells in vitro was markedly increased compared to untargeted pEGylated polyplexes, suggesting targeted gene delivery.

Influence of neutron irradiation on holmium acetylacetonate loaded poly(L-lactic acid) microspheres

Holmium-loaded microspheres are useful systems in radio-embolization therapy of liver metastases. For administration to a patient, the holmium-loaded microspheres have to be irradiated in a nuclear reactor to become radioactive. In this paper. the influence of neutron irradiation on poly(L-lactic acid) (PLLA) microspheres and films, with or without holmium acetylacetonate (HoAcAc), is investigated, in particular using differential scanning calorimetry (MDSC), scanning electron microscopy, gel permeation chromatography (GPC), infrared spectroscopy, and X-ray diffraction. After irradiation of the microspheres, only minor surface changes were seen using scanning electron microscopy, and the holmium complex remained immobilized in the polymer matrix as reflected by a relatively small release of this complex. GPC and MDSC measurements showed a decrease in molecular weight and crystallinity of the PLLA, respectively, which can be ascribed to radiation induced chain scission. Irradiation of the HoAcAc loaded PLLA matrices resulted in evaporation of the non-coordinated and one coordinated water molecule of the HoAcAc complex, as evidenced by MDSC and X-ray diffraction analysis. Infrared spectroscopy indicated that some degradation of the acetylacetonate anion occurred after irradiation. Although some radiation induced damage of both the PLLA matrix and the embedded HoAcAc-complex occurs, the microspheres retain their favourable properties (no marginal release of Ho, preservation of the microsphere size), which make these systems interesting candidates for the treatment of tumours by radio-embolization.

Pore sizes in hydrated dextran microspheres

The average pore size of hydrated dextran microspheres is derived from rheological and protein release data. The microspheres were prepared by cross-linking an aqueous solution of methacrylated dextran emulsified in a continuous poly(ethylene glycol) phase. The rheological data were obtained using a novel micromanipulation technique, which enables the compression of a single microsphere. The so obtained pseudoelasticity moduli of the microspheres were derived from these compression data and corresponded well with the elasticity moduli of macroscopic hydrogels of the same composition, as determined with dynamic mechanical analysis. The modulus increased with decreasing water contents of the microspheres and with increasing degrees of methacrylate substitution of the dextran used. Furthermore, the average pore sizes calculated from the pseudoelasticity moduli were in good agreement with the pore sizes derived from protein release data. In conclusion, this study shows that micromanipulation provides insight into the average pore sizes of dextran microspheres, which is an important characteristic that will modulate the release of encapsulated proteins.

Novel crosslinking methods to design hydrogels

Hydrogels are presently under investigation as matrices for the controlled release of bioactive molecules, in particular pharmaceutical proteins, and for the encapsulation of living cells. For these applications, it is often required that the gels degrade under physiological conditions. This means that the originally three-dimensional structure has to disintegrate preferably in harmless products to ensure a good biocompatibility of the hydrogel. In this overview, different chemical and physical crosslinking methods used for the design of biodegradable hydrogels are summarized and discussed. Chemical crosslinking is a highly versatile method to create hydrogels with good mechanical stability. However, the crosslinking agents used are often toxic compounds, which have been extracted from the gels before they can be applied. Moreover, crosslinking agents can give unwanted reactions with the bioactive substances present in the hydrogel matrix. Such adverse effects are avoided with the use of physically crosslinked gels.

Release of recombinant human interleukin-2 from dextran-based hydrogels

In this study, the release of recombinant human interleukin-2 (rhIL-2) from methacrylated dextran (dex-MA) and (lactate-)hydroxyethyl methacrylated dextran (dex-(lactate-)HEMA) hydrogels with varying crosslink density was investigated. Hydrogels derived from dex-MA are stable under physiological conditions (pH 7 and 37 degrees C), whereas dex-HEMA and dex-lactate-HEMA hydrogels degrade due to the presence of hydrolytically sensitive esters in the crosslinks of the gels. The protein release profiles both the non-degradable and degradable dextran-based hydrogels showed that with increasing crosslink density of the gel, the release of rhIL-2 decreases. From dex-MA hydrogels with an initial water content above 70%, the rhIL-2 release followed Fickian diffusion, whereas from gels with an initial water content of 70% or lower the protein was fully entrapped in the hydrogel meshes. In contrast with non-degradable dex-MA hydrogels, degradable dex-lactate-HEMA gels with comparable network characteristics (degree of methacrylate substitution and initial water content) showed an almost zero-order, degradation controlled release of rhIL-2 in a time period of 5-15 days. This paper demonstrates that the release of rhIL-2 from non-degradable dex-MA and degradable dex-lactate-HEMA gels can be modulated by the crosslink density and/or the degradation characteristics of the hydrogel. Importantly, rhIL-2 was mainly released as monomer from the hydrogels and with good retention of its biological activity.

Advances in nuclear oncology: microspheres for internal radionuclide therapy of liver tumours

Liver metastases cause the majority of deaths from colorectal cancer, and response to chemotherapy and external radiotherapy is poor. An alternative is internal radionuclide therapy using (90)Y labeled microspheres. These microspheres are very stable and have a proven efficacy in the field of treatment of primary or metastatic hepatic cancer. Whilst these glass spheres showed encouraging results in patients, their high density is a serious drawback. Currently, other materials with lower densities and other radioisotopes are being investigated in order to optimize this promising new therapy. Three major radiolabeled microsphere materials, viz. glass, resin-based and polymer-based, are now available for therapy or are being tested in animals. In this review the preparation, stability and degradation of these spheres are discussed.

On the release of proteins from degrading dextran methacrylate hydrogels and the correlation with the rheologic properties of the hydrogels

PURPOSE

To study the release of macromolecules of different sizes (bovine serum albumin, immunoglobulin G) from degrading (addition of dextranase) dextran methacrylate (dex-MA) hydrogels and to correlate the release with the evolution of the rehologic properties of the hydrogels during degradation.

METHODS

The size of the macromolecules, the degree of substitution (i.e., number of methacrylates per 100 glycopyranose residues) of the dex-MA and the dextranase concentration in the hydrogels was varied. The rheologic properties were measured with a controlled stress rheometer.

RESULTS

The release from dex-MA hydrogels without dextranase was very small [7-20% (time frame up to 180 days)] showing that most of the molecules were entrapped within the hydrogel network. The release from degrading dex-MA hydrogels followed zero-order kinetics for all molecules during a substantial period of the release. This was explained by a liberation and an increasing diffusivity of the proteins in the course of the degradation. The total amount released and the release rates could be well correlated with the rheologically observed degradation rates.

CONCLUSIONS

It was shown that rheology can be a useful tool to help explain the release from degrading hydrogels.

Characterization of poly(L-lactic acid) microspheres loaded with holmium acetylacetonate

Holmium-loaded PLLA microspheres are useful systems in radioembolization therapy of liver metastases because of their low density, biodegradability and favourable radiation characteristics. Neutron activated Ho-loaded microspheres showed a surprisingly low release of the relatively small holmium complex. In this paper factors responsible for this behaviour are investigated, in particular by the use of differential scanning calorimetry, scanning electron microscopy, infrared spectroscopy and X-ray diffraction. The holmium complex is soluble in PLLA up to 8% in films and 17% in microspheres. Interactions between carbonyl groups of PLLA, and the Ho-ion in the HoAcAc complex, explain very satisfactorily the high stability of holmium-loaded microspheres.

Fourier transform infrared spectrometric analysis of protein conformation: effect of sampling method and stress factors

Changes in the amide bands in Fourier transform infrared spectra of proteins are generally attributed to alterations in protein secondary structure. In this study spectra of five different globular proteins were compared in the solid and solution states recorded with several sampling techniques. Spectral differences for each protein were observed between the various sampling techniques and physical states, which could not all be explained by a change in protein secondary structure. For example, lyophilization in the absence of lyoprotectants caused spectral changes that could (partially) have been caused by the removal of hydrating water molecules rather than secondary structural changes. Moreover, attenuated total reflectance spectra of proteins in H2O were not directly comparable to transmission spectra due to the anomalous dispersion effect. Our study also revealed that the amide I, II, and III bands differ in their sensitivities to changes in protein conformation: For example, strong bands in the region 1620-1630 and 1685-1695 cm(-1) were seen in the amide I region of aggregated protein spectra. Surprisingly, absorbance of such magnitudes was not observed in the amide II and III region. It appears, therefore, that only the amide I can be used to distinguish between intra- and intermolecular beta-sheet formation. Considering the differing sensitivity of the different amide modes to structural changes, it is advisable to utilize not only the amide I band, but also the amide II and III bands, to determine changes in protein secondary structure. Finally, it is important to realize that changes in these bands may not always correspond to secondary structural changes of the proteins.

Tumour embolization of the Vx2 rabbit head and neck cancer model with Dextran hydrogel and Holmium-poly(L-lactic acid) microspheres: a radionuclide and histological pilot study

INTRODUCTION

Intra-arterial embolization of unresectable malignant tumours with biodegradable microspheres is an effective way of selective anti-tumour therapy. Promising candidates are Dextran hydrogel (Dex) microspheres for chemo-embolization and Holmium-166 poly(L-lactic acid) (166HoPLA) microspheres for radio-embolization. This study was performed to investigate the distribution of intra-arterially injected microspheres both in vivo and histologically in order to establish an optimal size of particles for embolization of head and neck tumours.

MATERIAL

Twenty rabbits with Vx2 auricular tumours were embolized via the caudal auricular artery with 4 different batches of microspheres: Radioactive (166)HoPLA microspheres sieved between 20 and 50 microm and Dextran hydrogel microspheres sieved between 20 and 100 microm (Dex20), 30 and 100 microm (Dex30) or 50 and 100 microm (Dex50). Dex20 and Dex50 microspheres were labelled with 99mTechnetium in six cases.

METHODS

The average particle size of the microspheres was determined. The proportion of microspheres entrapped in the tumour was measured with a gamma camera. The distribution of microspheres around the primary tumour and spill of particles over into lungs or other organs was analysed from histological sections.

RESULTS

The mean particle diameter varied from 19 to 66 microm: (166)HoPLA 19+/-11 microm, Dex20 40+/-19 microm, Dex30 50+/-19 microm, Dex50 66+/-21 microm. The 19 microm(166)HoPLA particles proved inadequate for embolization as 51% spilled over into the lungs, whereas over 95% of the 40-66 microm Dex microspheres were retained within the primary tumour area. Particle density in lung tissues proved significantly lower for the Dex50 group. Stray emboli to the brain occurred in two rabbits.

CONCLUSION

The results of this investigation show that both Dextran hydrogel and holmium-166 poly(L-lactic acid) microspheres are potential candidates for embolization of head and neck cancer. In future studies, arterio-arteriolar anastomoses which might confound treatment should be identified and occluded. Particles with a number weighted mean diameter of at least 40 microm and a volume weighted mean size up to 70 microm should be used.

Oxidation of recombinant human interleukin-2 by potassium peroxodisulfate

PURPOSE

The oxidation of recombinant human interleukin-2 (rhlL-2) by potassium peroxodisulfate (KPS) with or without N,N,N',N'-tetramethylethylenediamine (TEMED), which are used for the preparation of dextran-based hydrogels, was investigated.

METHODS

The oxidation of (derivatives of) methionine. tryptophan, histidine and tyrosine, as well as rhlL-2 was investigated. Both the oxidation kinetics (RP-HPLC) and the nature of the oxidation products (mass spectrometry) were studied as a function of the KPS and TEMED concentration, and the presence of a competitive antioxidant, methionine.

RESULTS

Under conditions relevant for the preparation of rhIL-2 loaded hydrogels, only methionine and tryptophan derivatives were susceptible to oxidation by KPS. The oxidation of these compounds was inhibited once TEMED was present, suggesting that the peroxodisulfate anion, rather than the radicals formed in the presence of TEMED, is the oxidative species. KPS only induced oxidation of the four methionines present in rhIL-2, whereas the tryptophan residue remained unaffected. The radicals, formed after KPS decomposition by TEMED, induced some dimerization of rhIL-2. The oxidation of rhIL-2 could be substantially reduced by the addition of methionine, or by pre-incubation of KPS with TEMED.

CONCLUSIONS

Only the methionine residues in rhlL-2 are oxidized by KPS. The extent of oxidation can be minimized by a proper selection of the reaction conditions.

A comparative biocompatibility study of microspheres based on crosslinked dextran or poly(lactic-co-glycolic)acid after subcutaneous injection in rats

Microspheres based on methacrylated dextran (dex-MA), dextran derivatized with lactate-hydroxyethyl methacrylate (dex-lactate-HEMA) or derivatized with HEMA (dex-HEMA) were prepared. The microspheres were injected subcutaneously in rats and the effect of the particle size and network characteristics [initial water content and degree of methacrylate substitution (DS)] on the tissue reaction was investigated for 6 weeks. As a control, poly(lactic-co-glycolic)acid (PLGA) microspheres with varying sizes (unsized, smaller than 10 microm, smaller and larger than 20 microm) were injected as well. A mild tissue reaction to the PLGA microspheres was observed, characterized by infiltration of macrophages (MØs) and some granulocytes. Six weeks postinjection, the PLGA microspheres were still present. However, their size was decreased indicating degradation and many spheres had been phagocytosed. The tissue reaction was hardly affected by size differences, except for particles smaller than 10 microm, which induced an extensive tissue reaction. The initial tissue reaction to nondegradable dex-MA microspheres was stronger than towards the PLGA microspheres, but at day 10 the tissue reactions were comparable for both groups. Six weeks postinjection, the dex-MA microspheres were completely phagocytosed, and no signs of degradation were observed. The size and initial water content of dex-MA microspheres hardly affected the tissue response, although less granulocytes were observed for microspheres with higher DS. Slowly degrading dextran microspheres composed of dex-(lactate(1)-)HEMA induced a tissue reaction comparable to the PLGA microspheres. However, degradation of the dex-(lactate(1,3)-)HEMA microspheres was associated with an increased number of MØ's and giant cells, both phagocytosing the microspheres and their degradation products. Similar to PLGA, no adverse reactions were observed for the nondegradable dex-MA and degradable dextran microspheres. This study shows that both nondegradable and degradable dextran-based microspheres are well tolerated after subcutaneous injection in rats, which make them interesting candidates as controlled drug delivery systems.

Formation of dextran hydrogels by crystallization

In this paper, a novel method is presented for the preparation of dextran hydrogels and microspheres, based on crystallization. Although dextrans are known to be well soluble in water, precipitation was observed in concentrated aqueous solutions of low molecular weight dextran (dextran 6000), whereas for solutions of dextran with higher molecular weights (dextran 40,000 and 220,000) no precipitation was observed in the time-frame studied. The kinetics of the precipitation process were studied and showed that precipitation was faster when more concentrated dextran solutions were used. Furthermore, the precipitation process was accelerated by stirring and by the presence of salts. Depending on the precipitation time, microspheres or gels were obtained. The precipitates were insoluble in water at room temperature, but readily dissolved in boiling water or DMSO. IR spectroscopy and (modulated) differential scanning calorimetry ((M)DSC) demonstrated that the precipitates were crystalline. We hypothesize that crystallization is due to association of the chains through hydrogen bonding, induced by the large polymer/water ratio in concentrated dextran 6000 solutions.

In vitro biocompatibility of biodegradable dextran-based hydrogels tested with human fibroblasts

The cytotoxicity of dextran T40, methacrylated dextran (dex-MA) and hydroxyethyl-methacrylated dextran (dex-HEMA), dextran-based hydrogel discs and microspheres, and their degradation products, was studied by measuring the cell proliferation inhibition index (CPII) on human fibroblasts in vitro. In addition, during the 72 h incubation period light-microscopic observations were performed daily. After 24 h of incubation with dextran and dex-HEMA polymers, the cells showed elongated or spider-like forms, some lipid droplets and intracellular granula, indicative of pinocytosis and internalization of the polymers. During the next two days, the fibroblasts' appearance did not change. Methacrylic acid (MAA), formed by hydrolysis of dex-HEMA, did not influence the cell morphology. Dex-HEMA polymer solutions with a low and high degree of substitution (DS) at 100 mg/ml caused a CPII of 30-40% after 72 h. This is less than 10% growth inhibition per cell cycle and statistically not different from the CPII induced by 100 mg/ml dextran T40. Growth inhibition induced by MAA was also low. The various dex-MA hydrogel discs caused similar low growth inhibition. Interestingly, hydrogel microspheres of dex-MA and dex-(lactate-)HEMA caused a CPII of only 0-20% after 72 h. The results presented in this study demonstrate that methacrylate-derivatized dextran hydrogels show good biocompatibility in vitro making these degradable biomaterials promising systems for drug delivery purposes.

Lipid-coated polyplexes for targeted gene delivery to ovarian carcinoma cells

A nonviral gene delivery vector has been developed in our laboratory based on the cationic polymer, poly(2-(dimethylethylamino)ethyl methacrylate) (p(DMAEMA)). p(DMAEMA)-based polyplexes have been successfully used for the transfection of OVCAR-3 cells in vitro. However, these polyplexes were unable to transfect OVCAR-3 cells growing in the peritoneal cavity of nude mice after intraperitoneal administration, which could be ascribed to inactivation by components (including hyaluronic acid) present in the tumor ascitic fluid. The present work aimed at (a) protecting p(DMAEMA)-based polyplexes against destabilization or inactivation by polyanions such as hyaluronic acid present in tumor ascitic fluid and (b) enhancing cellular uptake of the protected p(DMAEMA)-based polyplexes by targeting with antibody Fab' fragments. To fulfill these requirements, we have developed a detergent removal method to coat polyplexes with anionic lipids. With this method, spherical particles of approximately 125 nm, which were protected from destabilization by polyanions, were obtained. More importantly, the transfection efficiency of lipopolyplexes was unaffected in the presence of hyaluronic acid, indicating that lipid coating of polyplexes protects against destabilization by hyaluronic acid. By conjugating antibody Fab' fragments directed against the epithelial glycoprotein-2 to the lipidic surface of these lipopolyplexes, target cell-specific transfection of OVCAR-3 cells could be obtained in vitro.

Targeting of liver tumour in rats by selective delivery of holmium-166 loaded microspheres: a biodistribution study

Intra-arterial administration of beta-emitting particles that become trapped in the vascular bed of a tumour and remain there while delivering high doses, represents a unique approach in the treatment of both primary and metastatic liver tumours. Studies on selective internal radiation therapy of colorectal liver metastases using yttrium-90 glass microspheres have shown encouraging results. This study describes the biodistribution of 40-microm poly lactic acid microspheres loaded with radioactive holmium-166, after intra-arterial administration into the hepatic artery of rats with implanted liver tumours. Radioactivity measurements showed >95% retention of injected activity in the liver and its resident tumour. The average activity detected in other tissues was < or =0.1%ID/g, with incidental exceptions in the lungs and stomach. Very little 166Ho activity was detected in kidneys (<0.1%ID/g), thereby indicating the stability of the microspheres in vivo. Tumour targeting was very effective, with a mean tumour to liver ratio of 6. 1+/-2.9 for rats with tumour (n=15) versus 0.7+/-0.5 for control rats (n=6; P<0.001). These ratios were not significantly affected by the use of adrenaline. Histological analysis showed that five times as many large (>10) and medium-sized (4-9) clusters of microspheres were present within tumour and peritumoural tissue, compared with normal liver. Single microspheres were equally dispersed throughout the tumour, as well as normal liver parenchyma.