Chondrogenic potential of macroporous biodegradable cryogels based on synthetic poly(α-amino acids).

In this study, the potential of highly porous hydrogels based on biodegradable synthetic poly(α-amino acids) to support proliferation and chondrogenesis of human dental pulp stem cells (hDPSCs) was investigated. Covalently crosslinked gels with permanent pores were formed under cryogenic conditions by free-radical copolymerization of poly[N5-(2-hydroxyethyl)-l-glutamine-stat-N5-(2-methacryloyl-oxy-ethyl)-l-glutamine] (PHEG-MA) with 2-hydroxyethyl methacrylate (HEMA) and N-propargyl methacrylamide (PrMAAm) as minor co-monomers. PrMAAm provided alkyne groups for modifying the gels with cell-supporting moieties (RGDS peptides) by the azide-alkyne "click"-reaction. Two types of gels with different compressive moduli were prepared. Each type was modified with two different concentrations of RGDS peptide. X-ray computed nanotomography (nanoCT) was used to visualize and analyze the 3D-structure of the cryogels. It was shown that modifying the PHEG-MA cryogels within the range of RGDS concentrations examined here had a positive effect on the proliferation of hDPSCs. Immunofluorescence staining for collagen type 2 and aggrecan proved that there was differentiation of hDPSCs into chondrocytes.

Polymer brushes based on PLLA-b-PEO colloids for the preparation of protein resistant PLA surfaces.

In this study we investigate the formation of protein-resistant polymer surfaces, such as aliphatic polyesters, through the deposition of self-assemblies of amphiphilic poly(l-lactide)-b-poly(ethylene oxide), PLLA-b-PEO, copolymers as stable nanoparticles with a kinetically frozen PLLA core on model PLLA surfaces. The length of the PEO chains in the corona was tuned to achieve polymer brushes capable of preventing protein adsorption on PLA-based biomaterials. The spectroscopic ellipsometry, IR and XPS analysis, contact angle goniometry, and AFM proved that the PEO chains adopted a brush structure and were preferably exposed on the surface. The low-fouling properties of the physisorbed PLLA-b-PEO layers approached the ones of reactive grafting methods, as shown by surface plasmon resonance spectroscopy. The anti-fouling properties of the prepared PEO brushes provided sufficient interface to prevent cell adhesion as proved in vitro. Thus, the developed surface coating with PLLA-b-PEO colloids can provide an anti-fouling background for the creation of nanopatterned biofunctionalized surfaces in biomedical applications.

N-(2-hydroxypropyl) methacrylamide based cryogels--synthesis and biomimetic modification for stem cell applications.

The design of favorable mechanical properties and suitable surface modifications of hydrogels in order to stimulate specific cell response is a great challenge. N-(2-Hydroxypropyl) methacryl-amide (HPMA) was utilized to form macroporous cryogel scaffolds for stem cell applications. Furthermore, one group of scaffolds was enhanced by copolymerization of HPMA with methacryloyl-GGGRGDS-OH peptide in an effort to integrate biomimetic adhesion sites. The cryogels were characterized by stiffness and equilibrium swelling measurements as well as by scanning electron microscopy. Cell culture experiments were performed with human adipose-derived stem cells and substrates were found completely non-toxic. Moreover, RGDS-enriched cryogels supported cell attachment, spreading and proliferation, so they can be considered suitable for designed aims.

Nano-colloid printing of functionalized PLA-b-PEO copolymers: tailoring the surface pattern of adhesive motif and its effect on cell attachment.

In this study, we investigate the preparation of surface pattern of functional groups on poly(lactide) (PLA) surfaces through the controlled deposition of core-shell self-assemblies based on functionalized PLA-b-PEO amphiphilic block copolymers from selective solvents. Through grafting RGDS peptide onto the functionalized copolymer surface, the presented approach enables to prepare PLA surfaces with random and clustered spatial distribution of adhesive motifs. The proposed topography of the adhesion motif was proved by atomic force microscopy techniques using biotin-tagged RGDS peptide grafted on the surface and streptavidin-modified gold nanospheres which bind the tagged RGDS peptides as a contrast agent. The cell culture study under static and dynamic conditions with MG63 osteosarcoma cell line showed that the clustered distribution of RGDS peptides provided more efficient initial cell attachment and spreading, and resistance to cell detachment under dynamic culture compared to randomly distributed RGDS motif when with the same average RGDS peptide concentration.

In vivo vascularization of anisotropic channeled porous polylactide-based capsules for islet transplantation: the effects of scaffold architecture and implantation site.

The replacement of pancreatic islets for the possible treatment of type 1 diabetes is limited by the extremely high oxygen demand of the islets. To this end, here we hypothesize to create a novel extra-hepatic highly-vascularized bioartificial cavity using a porous scaffold as a template and using the host body as a living bioreactor for subsequent islet transplantation. Polylactide-based capsular-shaped anisotropic channeled porous scaffolds were prepared by following the unidirectional thermally-induced phase separation technique, and were implanted under the skin and in the greater omentum of Brown Norway rats. Polyamide mesh-based isotropic regular porous capsules were used as the controls. After 4weeks, the implants were excised and analyzed by histology. The hematoxylin and eosin, as well as Masson's trichrome staining, revealed a) low or no infiltration of giant inflammatory cells in the implant, b) minor but insignificant fibrosis around the implant, c) guided infiltration of host cells in the test capsule in contrast to random cell infiltration in the control capsule, and d) relatively superior cell infiltration in the capsules implanted in the greater omentum than in the capsules implanted under the skin. Furthermore, the anti-CD31 immunohistochemistry staining revealed numerous vessels at the implant site, but mostly on the external surface of the capsules. Taken together, the current study, the first of its kind, is a significant step-forward towards engineering a bioartificial microenvironment for the transplantation of islets.

Cell adhesion on artificial materials for tissue engineering.

Advanced interdisciplinary scientific field of tissue engineering has been developed to meet increasing demand for safe, functional and easy available substitutes of irreversibly damaged tissues and organs. First biomaterials were constructed as "two-dimensional" (allowing cell adhesion only on their surface), and durable (non-biodegradable). In contrast, biomaterials of new generation are characterized by so-called three dimensional porous or scaffold-like architecture promoting attachment, growth and differentiation of cells inside the material, accompanied by its gradual removal and replacement with regenerated fully functional tissue. In order to control these processes, these materials are endowed with a defined spectrum of bioactive molecules, such as ligands for adhesion receptors on cells, functional parts of natural growth factors, hormones and enzymes or synthetic regulators of cell behavior, incorporated in defined concentrations and spatial distribution against a bioinert background resistant to uncontrolled protein adsorption and cell adhesion.

Pharmacokinetics and distribution of 125I-PLA-b-PEO block copolymers in rats.

The PLA-b-PEO block copolymers were studied as potential carriers for anti-inflammatory and anticancer drugs. The copolymers were labeled with 125I, and their micelles in physiological saline were prepared by dialysis. Copolymer 1, with Mw = 12,360 (PLA/PEO = 7000/5000), formed particles of about 300 nm in diameter (Rh was 150 nm), whereas copolymer 2, with Mw = 20,470 (6000/14,000), made up micelles of about 72 nm in diameter (Rh was 35.8 nm). Their pharmacokinetic and biodistribution profiles were compared in normal rats and rats with carrageenan-induced inflammation after intravenous application of about 5 mg/kg of each copolymer. Copolymer 2, forming smaller particles, showed longer distribution and elimination half-lives. Both copolymers under study exhibited significantly higher uptake by inflammatory tissue compared with noninflammatory one. The study indicates that PLA-b-PEO copolymers, having different molecular weight of the chains, have similar biological behavior in most organs and tissues. Differences in the uptake by some organs (mainly kidney and bowels) and in activity level in blood at later time intervals were found. Significantly different clearance values are due to different ratios of hydrophobic and hydrophilic chains of the copolymers.

Functionalized surfaces of polylactide modified by Langmuir-Blodgett films of amphiphilic block copolymers.

To modify the surface of poly(L-lactide) (PLA) supports, we have investigated the feasibility to deposit on the PLA surface Langmuir-Blodgett films of amphiphilic block copolymers based on poly(L-lactide). AB and ABA block copolymers were prepared with PLA as the A block and either poly(ethylene oxide), alpha-methoxy-omega-hydroxy poly(ethylene oxide), alpha-carboxy-omega-hydroxy poly(ethylene oxide) or poly(L-aspartic acid) as the B blocks. Films with phase-separated hydrophilic and hydrophobic blocks in a bilayer "brush" structure were prepared by compression of the copolymer Langmuir films on the water/air interface. The interfacial behavior of the monolayers and the effect of the copolymer composition on the phase separation was followed by measurements of the surface-pressure/area isotherms using a Langmuir trough and by contact angle measurement of deposited Langmuir-Blodgett (LB) films. The phase separation of the hydrophilic and PLA blocks is more effective in diblock AB copolymers compared with triblock ABA copolymers. The presence of ionic groups in the hydrophilic chains facilitates penetration of hydrophilic segments into the water subphase. Dynamic contact angle measurements were used to study the stability of the LB-films transferred on the PLA support and the changes in the surface properties upon incubation of surfaces in water.

Microdomain structure in polylactide-block-poly(ethylene oxide) copolymer films.

Structured surface is an important property of polymer biomaterials for tissue engineering, for its capacity to expose domains with different surface energy and functional groups. For this purpose, amphiphilic A-B-A block copolymers with polylactide (PLA) as A blocks and poly(ethylene oxide) (PEO 3, Mn = 3090; PEO6, Mn = 6110) as B block were synthesized by ring-opening polymerization of either L-lactide (L-LA) or DL-lactide (DL-LA), using poly(ethylene glycol)s as macroinitiators and tin(II) octanoate (Sn(Oct)2) as a catalyst. Differential scanning calorimetry (DSC) and electron microscopy were used to study the phase separation of the hydrophobic (PLA) and hydrophilic (PEO) segments in films made of the copolymers and their blends with high-molecular-weight PLA homopolymers. Hydrophilic (PEO) and hydrophobic (PLA) domains were formed at the polymer film surface due to the separation of phases. The phase separation was affected by the copolymer composition and the stereoregularity of PLA blocks in the copolymers.

Solute absorption from the airways of the isolated rat lung. V. Charge effects on the absorption of copolymers of N(2-hydroxyethyl)-DL-aspartamide with DL-aspartic acid or dimethylaminopropyl-DL-aspartamide.

PURPOSE: To determine the effects of ionized substituents upon the pulmonary absorption of 6-8 kDa synthetic, hydrophilic polypeptides. METHODS: Fluorophore-labeled poly (hydroxyethylaspartamide), F-PHEA (neutral at pH 7.4) and its copolymer derivatives poly (hydroxyethylaspartamide-co-dimethylaminopropylaspartamide), F-P(HEA-DMAPA) (positive at pH 7.4) and poly (hydroxyethylaspartamide-co-aspartic acid), F-P(HEA-AA) (negative at pH 7.4) were synthesized and administered in different concentrations to the airways of the isolated rat lung preparation. The time and molecular weight dependencies of polypeptide absorption into perfusate were determined at intervals by gel permeation chromatography. RESULTS: For all polypeptides, molecular weights in perfusate were about 1 kDa less than those which were administered, due to preferential absorption of smaller molecules. The absorption, up to 70% of the administered dose over 3 h, of the anionic F-P(HEA-AA), was significantly faster than that of the neutral F-PHEA or the polycationic F-P(HEA-DMAPA). The latter derivative produced greatest edema in the lung. Absorption showed both active [dose-dependent kinetics] and passive [diffusive] components for all three polymers. CONCLUSIONS: Pulmonary absorption of similarly sized macromolecular PHEA derivatives, either neutral, positively or negatively charged, occured via carrier-mediated and diffusive mechanisms. The highest rate of absorption was observed with the polyanionic derivative.

New radiopaque polyHEMA-based hydrogel particles.

New iodine-containing polymeric hydrogel particles were prepared by suspension radical copolymerization of 2-hydroxyethyl methacrylate (HEMA), 3-(methacryloylamidoacetamido)-2,4,6-triiodobenzoic acid (MABA) and ethylene dimethacrylate (EDMA) in an aqueous medium using azobisisobutyronitrile as an initiator and magnesium hydroxide as a suspension stabilizer. To impart porosity to the product, cyclohexanol and 1-dodecanol were added as inert diluents to the polymerization mixture. Particles containing 27 wt % iodine produced radiopacity sufficient to observe a clearly visible X-ray image. The equilibrium swelling behavior of the particles in water was characterized. Swelling of the particles dramatically increased by converting the acid groups of MABA into their Na+ form. The more MABA the copolymer particle contain, the higher is their swelling in the Na+ form.

Synthetic macromolecular inhibitors of human leukocyte elastase. 1. Synthesis of peptidyl carbamates bound to water-soluble polymers: poly-alpha,beta-[N-(2-hydroxyethyl)-D,L-aspartamide] and poly-alpha-[N5-(2-hydroxyethyl)-L-glutamine].

The design and synthesis of macromolecular peptidyl carbamate inhibitors of human leukocyte elastase (HLE), based on coupling of a low-molecular-weight peptidyl carbamate, succinylalanylalanylprolylmethyl isopropyl carbamate, with a linear hydrophilic polymer, poly-alpha,beta-[N-(2-hydroxyethyl)-D,L-aspartamide] or poly-alpha-[N5-(2-hydroxyethyl)-L-glutamine], is described. The covalent linkage between a flexible linear polymer and a peptidyl carbamate inhibitor of HLE did not compromise in vitro inhibitory capacity. The macromolecular peptidyl carbamates reported here represent a novel class of elastase inhibitors with a Ki ranging from 35.5 to 2.0 nM.

Solute absorption from the airways of the isolated rat lung. IV. Mechanisms of absorption of fluorophore-labeled poly-alpha,beta-[N(2-hydroxyethyl)-DL-aspartamide].

The pulmonary absorption kinetics of a single molecular weight distribution (MWD) of fluorophore-labeled poly-alpha,beta-[N(2-hydroxyethyl)-DL-aspartamide] (F-PHEA), a hydrophilic and biocompatible synthetic polypeptide, were studied in the isolated, perfused rat lung (iprl) as functions of administered polymer concentration, dose, vehicle, and presence and absence of fluorophore. The MWD was characterized before and after absorption by measurement of weight- and number-averaged molecular weights (Mw and Mn, respectively) using high-performance gel-permeation chromatography. Values for Mw and Mn were 8.6 and 5.3 kD before, and 6.7 and 4.7 kD after, absorption into the perfusate; there was no significant metabolism and the MWD of the absorbed polymer was independent of both dose and sampling time over a 3-hr period. F-PHEA failed to show any evidence of aggregation in solution or changes in dose distribution within the airways as functions of increasing polymer concentration and dose. A concentration ranging study indicated the presence of a saturable, carrier-mediated transport process for F-PHEA with a maximum absorption rate, Vmax, of approximately 180 micrograms or 0.027 mumol/hr. Coadministration of fluorophore-free PHEA was capable of depressing the absorption of F-PHEA. The transport process for F-PHEA appeared to have a molecular weight limit of about 7 kD for this hydrophilic polymer.

A study of enzymic degradation of a macromolecular substrate, poly[N5-(2-hydroxyethyl)-L-glutamine], by gel permeation chromatography and kinetic modelling.

The enzymatic degradation of poly[N5-(2-hydroxyethyl)-L-glutamine] (PHEG) by papain was investigated with the aim of evaluating the role of the random and/or a non-random mechanism of cleavage. The random degradation was modelled experimentally by the reaction of PHEG with ethanolamine. Assuming that different mechanisms of cleavage would yield different molecular weight distributions (MWDs) of the polymer degraded to the same degree, the evaluation was based on the comparison of experimental MWDs, measured by gel permeation chromatography, with MWDs simulated kinetically for the assumed mechanism of degradation. While a very good fit through a broad range of degradation conversions was obtained between the MWDs simulated for a random process and the experimental MWDs of the degradation of PHEG by ethanolamine, the enzymic degradation of PHEG by papain was certainly not a random process. Two models were found to be compatible with the chromatographic data: (i) a multiple attack assuming that the subsequent cleavage may proceed only on one of the two fragments produced by the previous attack, or (ii) a model which assumes that the degradation rate of one bond in a macromolecule of molecular weight M is proportional to M-1/3, i.e. a model which stresses the role of the surface of the polymer coil. In both simulations of enzymic degradation, the two bonds on each end of the PHEG chain were assumed not be cleavable.

Polymer-bound enzyme inhibitors: synthesis, properties, and physiological relevance.

For the most part, the pharmacological effect of an enzyme inhibitor results from its interaction with a single target molecule--the target enzyme. In many cases, the inhibitor moiety can interact effectively with the enzyme without necessarily being released from the polymer carrier. In the simplest form, i.e., the inhibition of an extracellular enzyme, this interaction can be understood as being two macromolecules in a solution--a reaction that can be readily modeled in vitro. Thus, enzyme inhibitors are very suitable for preparing polymer-bound drugs for investigative purposes or therapeutical applications. The macromolecular properties of polymers impact on the pharmacokinetic behavior of the compound because of the controlled intercompartmental transport. The physiological significance of the polymer-bound enzyme inhibitors is considered herein regarding the factors controlling the biodistribution of polymers among the physiological compartments. Extracellular proteinases and lysosomal enzymes are the most easily approachable targets. Strategies for preparation of polymer-bound inhibitors are discussed.

Solute absorption from the airways of the isolated rat lung. III. Absorption of several peptidase-resistant, synthetic polypeptides: poly-(2-hydroxyethyl)-aspartamides.

A series of samples of the synthetic polypeptide poly-alpha, beta-[N(2-hydroxyethyl)-DL-aspartamide] (PHEA), containing covalently bound fluorophore, ethylcarbonyl-6-aminofluorescein, and exhibiting different molecular weight distributions with weight average molecular weights ranging from approximately 4 to 43 kD, was prepared and characterized. Aqueous solutions of the polymers were administered to the airways of isolated perfused rat lung preparations, and transfer to the perfusate was measured. Polymers administered directly to the perfusate were not degraded during the experiment. Polymer transfer rates were dependent upon starting molecular weight distribution, larger molecules being absorbed more slowly. In the case of a polymer with a median molecular weight of 7.2 kD, the absorbed species appeared to be smaller molecules than those which were originally administered. This was not the case for a 3.98-kD polymer; absorbed material had a gel permeation chromatography elution volume equivalent to that of the administered material. Absorption for the 3.98-kD polymer was found to be dose dependent. Approximately 70% absorption of a 0.2-mg dose occurred in 100 min. Much larger polymers (up to 11.65 kD) were also absorbed at finite rates. Results are discussed in the context of macromolecular delivery to the systemic circulation via the lung.

Transport of novel ovum surrogates in the human fallopian tube: a clinical study.

Functional inadequacy of the fallopian tube cannot be adequately diagnosed by classical tubal patency tests. A new method using novel ova surrogates, microspheres transport test, is designed to diagnose dysfunctional tubal sterility. Biodegradable test microspheres with diameters matching that of the native ovum were used. According to the optimum procedure, the suspension of test microspheres was applied through the vaginal wall into the Douglas' space under local anesthesia, and the transported microspheres were collected in a modified cervical cap. The microspheres were readily identified in the sediment of cervical secretion by their fluorescence. The method was tested in 139 long-term infertility patients. Transport was observed in 100% of the control group, and positive correlation between the transport findings and the anticipated frequencies of dysfunctional tubal sterility cases in other groups was found. Optimum diameter of test microspheres was estimated at about 175 microns. The test appears to be useful for examination of functional disorders of the ovum transport in human practice.

Degradation of N5-(2-hydroxyethyl)-L-glutamine and L-glutamic acid homopolymers and copolymers by papain.

The rate of degradation of poly[N5-(2-hydroxyethyl)-L-glutamine] (PHEG), poly(L-glutamic acid) (PGA) and poly[HEG-co-GA] random copolymers by papain was measured in the pH range 4.0-7.5, employing the gel permeation chromatography method. The effect of the degree of ionization on the polymer conformation was measured by circular dichroism (c.d.). PHEG, which is uncharged, had a random coil conformation and an almost constant degradation rate within the whole pH interval. The ionization of PGA increased with increasing pH and was accompanied by conformational transition from helix to random coil. The hydrolysis of PGA by papain depended on pH with the optimum at about pH 5, indicating that both the high content of helix (at pH less than 5) and increasing charge density (at pH greater than 5), decreased the degradation rate. Contrary to PGA, pH profiles of the degradation rate of poly[HEG-co-GA] copolymers are monotonous and do not decrease at pH less than 5. In the copolymers the HEG residues act as a helix breaker and limit the formation of helical conformation. The role of structural features of a macromolecular substrate, i.e. the charge, helical conformation and the nature of amino acid residues, in the interaction between enzyme and polymer is discussed.

Characterization of the adsorptive pinocytic capture of a polyaspartamide modified by the incorporation of tyramine residues.

Previously it has been shown (Duncan, R., Starling, D., Rypácek, F., Drobník, J. and Lloyd, J.B. (1982) Biochim. Biophys. Acta 717, 248-254) that incorporation of tyramine residues into poly (alpha, beta-(N-2-hydroxyethyl]-DL-aspartamide (PHEA) greatly increases its rate of pinocytic uptake by rat visceral yolk sacs cultured in vitro. Here we describe the relationship between the tyramine content (1.2-21.9 mol%) of modified PHEA and its rate of uptake by yolk sacs. Above a level of substitution of approximately 10 mol% the rate of uptake rises rapidly, and the concentration-dependence of capture is indicative of uptake by adsorptive pinocytosis. Serum proteins were shown to compete effectively for membrane binding sites, indicating a nonspecific interaction of PHEA-derivatives with the yolk sac membrane. PHEA derivatives of the same tyramine content, but of different mean molecular weights (Mr), were captured at the same rates.