Evaluation of polyanion-coated biodegradable polymeric micelles as drug delivery vehicles.

Polymeric micelles, as drug delivery vehicles, must achieve specific targeting and high stability in the body for efficient drug delivery. We recently reported the preparation of polyanion-coated biodegradable polymeric micelles by coating positively charged polymeric micelles consisting of poly(L-lysine)-block-poly(L-lactide) (PLys-b-PLLA) AB diblock copolymers with anionic hyaluronic acid (HA) by polyion complex (PIC) formation. The obtained HA-coated micelles showed significantly higher stability in aqueous solution. In this study, to evaluate the HA-coated polymeric micelles as a drug carrier, model drug release from the micelles and cytotoxicity of the micelles were investigated. The HA-coated micelles showed sustained release of model drugs and low cytotoxicity. It is known that there are receptors for HA on liver sinusoidal endothelial cells (LSEC). Specific interactions of HA-coated micelles with LSECs and Kupffer cells were investigated and compared with polymeric micelles coated with other polyanionic polysaccharides, i.e., heparin (Hep) and carboxymethyl-dextran (CMDex). Although Hep-coated micelles and CMDex-coated micelles were incorporated into both Kupffer cells and LSECs, HA-coated micelles were taken up only into LSECs. These results suggest HA-coated micelles have potential utility as drug delivery vehicles exhibiting specific accumulation into LSECs.

Hydrophobically modified biodegradable poly(ethylene glycol) copolymers that form temperature-responsive Nanogels.

Biodegradable copolymers consisting of a hydrophilic poly[l-aspartic acid-alt-poly(ethylene glycol)] (poly(l-Asp-alt-PEG)) backbone and hydrophobic capryl units as side chains were synthesized. The amphiphilic copolymer was found to form nanosized hydrogel particles (nanogels) of approximately 15 nm in size by self-assembly at 20 degrees C in aqueous media, and the nanogel solutions displayed phase-transition in response to temperature. The transition of the nanogel solution was reversible and tunable in the range from 19 to 55 degrees C by variation of the amounts of capryl units introduced and the solution concentration. The nanogels were gradually degraded within days in a phosphate buffer solution (PBS) at 37 degrees C. Temperature-responsive biodegradable nanogel systems consisting of biocompatible PEG may have potential utility for high biocompatibility temperature-responsive nanodevices such as microreactor systems, molecular-chaperones, and drug delivery vehicles.

Polyrotaxane composed of poly-L-lactide and alpha-cyclodextrin exhibiting protease-triggered hydrolysis.

Biodegradable polyrotaxanes (PRXs) were synthesized from bis-amino-terminated poly(L-lactide) (PLLA) and alpha-cyclodextrin (alpha-CD), combined with capping by bulky end groups at the amino-termini of PLLA through enzymatically cleavable peptide linkages. The crystalline structure of the PRXs in the solid state was investigated by wide-angle X-ray diffraction (WAXRD), and the results suggested that PRX forms a column-type crystalline structure. Hydrolysis of ester bonds of the PLLA in PRX was prevented due to the supramolecular structure. However, in the presence of a protease (papain), the hydrolysis of PLLA in PRX was induced. The removal of the bulky end groups by the protease acted as a trigger for the release of alpha-CD and allowed hydrolysis of the PLLA ester bonds. Such unique hydrolysis behavior, that is, proteinase-triggered degradation of a polyester, was achieved by the combination of the supramolecular architecture, biodegradable PLLA, and enzymatically cleavable end groups.

Biodegradable shape-memory polymers exhibiting sharp thermal transitions and controlled drug release.

Biodegradable shape-memory polymer networks prepared by cross-linking star shape branched oligo(ε-caprolactone) (bOCL) with hexamethylene diisocyanate are introduced. The thermal and mechanical properties of these networks were investigated using differential scanning calorimetry and tensile testing, respectively, and the morphology of the phase structure was characterized by polarized optical microscopy. The shape-memory properties of the networks were quantified using thermomechanical tensile experiments and showed strain fixity rates R(f) higher than 97% and strain recovery rates R(r) as high as 100%. Of note, networks of OCL segments with a lower degree of polymerization (DP; 10) exhibited significantly improved temperature-sensitive shape recovery: 90% of the permanent shape was recovered upon heating to within a 2 °C range (37-39 °C). The networks exhibited complete shape recovery to the permanent shape within 10 s at 42 °C. Theophylline-loaded (10 and 20 wt %) shape-memory materials, prepared by cross-linking bOCL with hexamethylene diisocyanate in the presence of theophylline, are also described as a model for a controlled drug release device. The 10 wt % loaded material was sufficiently soft and flexible for complex shape transformation and also showed high R(f) (98%) and R(r) (99%). Sustained release of loaded theophylline was achieved over 1 month without initial burst-release in a phosphate buffer solution (PBS; pH 7.4) at 37 °C.

Polyassembly formation of complementary half-sliding oligo-DNAs and atomic force microscopic observation.

Oligonucleotides, especially oligo-DNAs, are useful building blocks for construction nanometer scale ordered architectures. Many researchers have been carried out to construct nano-architectures using complementary hydrogen bonding of DNAs. However, in order to achieve rational and robust design of various functional nano-architectures using DNAs, it is extremely important to establish basic principles of assembly patterns of oligo-DNAs based on their complementarity. In this study, to obtain basic information of polyassembly for simple oligo-DNA systems, formation of multiple assemblies of complementary half-sliding oligo-DNAs (cHSOs) was investigated with varying the length and sequence (GC content). A pairs of cHSOs were mixed in combination of complementary each other, and then the formation of high-molecular-weight polyassembly was evaluated by polyacrylamide gel electrophoresis (PAGE) and size exclusion chromatography (SEC). Moreover, the morphology and shape of the polyassembly was investigated by atomic force microscope (AFM) observation on mica. The obtained polyassembly displayed linear and networked morphology, and the continuous length and patterns of the assembly was depend on the length, GC contents and the concentration of the cHSOs.

Biodegradable nanogels prepared by self-assembly of poly(L-lactide)-grafted dextran: entrapment and release of proteins.

We showed previously that poly(L-lactide)-grafted dextran could form biodegradable nanogels in water. In this paper, various properties of Dex-g-PLLA nanogels were compared with Dex-Chol (dextran-cholesterol conjugate) nanogels to investigate the effects of hydrophobic units. Dex-g-PLLA nanogels exhibited significantly lower CAC and higher colloidal stability, indicating a strong tendency to form nanogels. We prepared lysozyme-loaded Dex-g-PLLA nanogels, and they exhibited a sustained release of lysozyme for 1 week without denaturation in PBS at 37 degrees C. The Dex-g-PLLA nanogels therefore have great potential as a delivery vehicle for therapeutic protein.

Construction of supramolecular assemblies and self-organized structures using oligo-DNAs.

To obtain fundamental theories for construction of self-organized structures using oligonucleotides, we constructed multiple aggregates with half-sliding oligo-DNAs. We used several types of half-sliding oligo-DNAs with different stability and number of residues. The formation of multiple aggregates by the oligo-DNAs was confirmed by size exclusion chromatography (SEC). The shape of the aggregates was investigated by atomic force microscope (AFM), and linear structures of multiple aggregates of half-sliding oligo-DNAs were observed.

Exhibition of soft and tenacious characteristics based on liquid crystal formation by introduction of cholesterol groups on biodegradable lactide copolymer.

Cholesterol side-functionalized poly(depsipeptide- co- dl-lactide) (PGD- dl-LA-(cholesterol) n ) and poly(depsipeptide) (PGD-(cholesterol) n) were prepared as novel biodegradable liquid crystalline (LC) polymers. These polymer films exhibited different LC phases depending on the cholesterol unit content in the polymers. The thermodynamic stability of these LC phases was quite high, and PGD-(cholesterol) n film exhibited continuous LC phases up to 202 degrees C. The resulting cholesterol LC phases were indicated to act as physical cross-linking points to form noncovalent network structures among the polymer chains. Therefore, PGD- dl-LA-(cholesterol) n film exhibited a rubbery and stretchy nature at 37 degrees C due to physical cross-linking points based on cholesterol LC phase well-dispersed in the film. The cholesterol side-group effects leading to rubbery character and hydrolytic resistance reported herein are rather unique. The biodegradable LC material exhibiting a soft and tenacious nature is a promising candidate for a new class of implant biomaterials used with dynamic organs of the body such as the heart and blood vessels.

Biodegradable nanogel formation of polylactide-grafted dextran copolymer in dilute aqueous solution and enhancement of its stability by stereocomplexation.

Monodisperse stereocomplex nanogels were obtained through the self-assembly of an equimolar mixture of dextran-graft-poly(L-lactide) (Dex-g-PLLA) and dextran-graft-poly(D-lactide) (Dex-g-PDLA) amphiphilic copolymers with well-defined composition in a dilute aqueous solution. The stereocomplex nanogel possessed partially crystallized cores of hydrophobic polylactide (PLA) and the hydrophilic dextran skeleton by intra- and/or intermolecular self-assembly between PLLA and PDLA chains. The stereocomplex nanogels exhibited significantly lower critical aggregation concentration (CAC) value as well as stronger thermodynamic stability compared with those of the corresponding L- or D-isomer nanogels. The mean diameter of the stereocomplex nanogels was 70 nm with narrow size distribution, implying they were well-defined and presumably nanogels. Furthermore, stereocomplex nanogel exhibited strong kinetic stability. The tunable degradation properties of Dex-g-PLA nanogels were achieved by varying the number of grafted PLA chains as well as applying stereocomplexation. This study demonstrates the advantage of stereocomplexation in the design of biodegradable nanogels with enhanced stability.

Suppression of cell and platelet adhesion to star-shaped 8-armed poly(ethylene glycol)-poly(L-lactide) block copolymer films.

To explore the potential of a star-shaped 8-armed poly(ethylene glycol)35K-block-poly(L-lactide)37K (8-armed PEG35K-b-PLLA37K: M(n) of PEG = 35 000, M(n) of PLLA = 37 000) film as a novel bioabsorbable adhesion-prevention membrane, the water structure, surface contact angle, protein adsorption, and cell and platelet anti-adhesion properties of such a hydrated film are investigated. Based on the results, it is found that the 8-armed PEG35K-b-PLLA37K film exhibits a biologically inert surface, which is the result of a large number of PEG chains and a free water layer on the film surface. This leads to a reduction in protein absorption and cell and platelet adhesion onto the film surface. This implies that the star-shaped 8-armed PEG35K-b-PLLA37K film can be utilized as a novel bioabsorbable adhesion-prevention membrane.

Preparation of a hyaluronic acid hydrogel through polyion complex formation using cationic polylactide-based microspheres as a biodegradable cross-linking agent.

A novel hyaluronic acid (HA)-based hydrogel was prepared through polyion complex (PIC) formation between cationic polylactide (PLA)-based microspheres (MS+) and hyaluronic acid (HA-) as an anionic polyelectrolyte. The MS+ and HA formed a biodegradable PIC hydrogel (HA-/MS+) when mixed in aqueous media. The swelling behavior and mechanical properties of the PIC hydrogel could be controlled by changing the charge ratio between HA- and MS+. In addition, the HA-/MS+ PIC hydrogel resulted in a lower inflammatory response compared with a collagen hydrogel in vivo.

Suppression of cell attachment and protein adsorption onto amphiphilic polylactide-grafted dextran films.

To develop novel biodegradable biomedical materials, polylactide-grafted dextrans (Dex-g-PLA)s having various lengths, numbers of graft chains and sugar units were synthesized using the trimethylsilyl (TMS) protection method. To explore the possibility of using Dex-g-PLA as a biomedical soft-material, the contact angle, cell attachment and protein adsorption properties of the films prepared from these biodegradable and amphiphilic graft co-polymers were investigated. The poly-L-lactide (PLLA) film did not absorb water at all because of its high hydrophobicity, while the graft co-polymer films started immediately to swell after immersion in PBS. The percentage of water absorption at equilibrium increased with increasing sugar unit content. The receding contact angle of the Dex-g-PLA films against water was smaller than that of the PLLA film. The receding contact angle of Dex-g-PLA films against water decreased with increasing the sugar unit content. The top surface of the Dex-g-PLA film was suggested to be covered with hydrophilic Dex segments by means of annealing in water and to afford the wettable surface. Such a wettable surface led to the suppression of cell attachment and protein adsorption onto the film.

Thermosensitive biodegradable polydepsipeptide.

A poly(N-isopropylacrylamide) (PNIPAAm)-like biodegradable thermosensitive polydepsipeptide, poly[Glc-Asn(N-isopropyl)], was synthesized by introducing an isopropyl amide group into poly[Glc-Asn]. Poly[Glc-Asn(N-isopropyl)] was degraded in vitro by cleavage of the ester bonds in the main chain in water at room temperature. The non-toxic nature of the polymer and its degradation products, coupled with a cloud point at 29 degrees C in water, make this polymer attractive for biomedical implant applications.

Formation of core-shell type biodegradable polymeric micelles from amphiphilic poly(aspartic acid)-block-polylactide diblock copolymer.

Poly(aspartic acid)-block-polylactide diblock copolymers (PAsp-b-PLAs) having both hydrophilic and hydrophobic segments of various lengths were synthesized. These PAsp-b-PLA diblock copolymers formed polymeric micelles consisting of a hydrophobic PLA core and a hydrophilic, pH-sensitive PAsp shell in aqueous solution. The effects of the segment length of both the PLA and the PAsp portions and the pH of the solution on the shapes and sizes of the PAsp-b-PLA polymeric micelles were investigated. The results indicated a balance between the effects of electrostatic repulsion, hydrogen bonding in the PAsp shell layer, and hydrophobic interactions in the PLA core determine the sizes of the PAsp-b-PLA polymeric micelles. Moreover, the PAsp-b-PLA polymeric micelles did not possess any cytotoxic activity against L929 fibroblast cells. The obtained polymeric micelle should be useful for biodegradable biomedical materials such as drug delivery vehicle.

Encapsulation and/or release behavior of bovine serum albumin within and from polylactide-grafted dextran microspheres.

Polylactide (PLA)-grafted dextran (Dex-graft-PLA) of various contents of sugar units was synthesized by anionic polymerization of L-lactide (L-LA) using the alkoxide of partially trimethylsilylated dextran (TMSDex) and subsequently removing the trimethylsilyl (TMS) groups. The copolymer showed different solubility from L-LA homopolymer with increasing the content of sugar units. We prepared bovine serum albumin (BSA)-loaded microspheres (MS)s according to a water-in-oil-in-water emulsion-solvent evaporation/extraction method using methylene chloride/DMSO as an organic cosolvent. MSs prepared from Dex-graft-PLA [MS(Dex-graft-PLA)s] exhibited higher loading efficiency of BSA than MSs prepared from PLLA [MS(PLLA)s]. The in vitro release rate of BSA from MS(Dex-graft-PLA) was faster than that from MS(PLLA). BSA released from MS(Dex-graft-PLA) maintained the secondary structure of native BSA to a great extent, compared with BSA released from MS(PLLA).

Cell growth on the porous sponges prepared from poly(depsipeptide-co-lactide) having various functional groups.

In tissue engineering, excellent biodegradable materials are desired as temporary scaffolds to support cell growth and disappear with the progress of tissue regeneration. We previously synthesized biodegradable poly(depsipeptide-co-lactide), poly[(Glc-Asp)-co-LA] and poly[(Glc-Lys)-co-LA], having reactive side-chain groups. Then, the effects of reactive and ionic side-chain groups on cell attachment and growth were investigated using co-polymer films with various amounts of carboxyl or amino groups. In this study, to evaluate the utility of these co-polymers as functional scaffolds for tissue regeneration, 3-dimensional porous sponges were prepared by freeze-drying method and the effects of reactive and ionic side-chain groups on cell growth and degradation behavior were investigated using co-polymer sponges with various amounts of carboxyl or amino groups. Good cell growth was observed on the co-polymer sponges. During cell culture, the co-polymer sponges exhibited various degradation rates related to the depsipeptide unit content. Three-dimensional biodegradable polymer matrices with reactive surface, controllable degradation behavior and good cell growth were successfully prepared using these co-polymers. Such kinds of co-polymer matrices are good candidate for scaffold for tissue engineering.

Design of attachment type of drug delivery system by complex formation of avidin with biotinyl drug model and biotinyl saccharide.

Recent studies have focused on the active targeting of drug delivery by combining a homing device and antitumor drug. For this purpose, synthesis of a well-designed vehicle (such as polymer/drug conjugates or nanoparticles) carrying a drug and a homing device requires many steps. We propose a new type of drug delivery system (DDS) by formation of a complex containing avidin (Av) plus biotinyl drug with a biotinyl homing device, which easily accommodates the combination of various drugs and homing devices. The targetable drug complex can be prepared by selecting an appropriate biotinyl drug derivative and a biotinyl homing device and mixing them with avidin. Fluorescent dye with 5-(and-6)-carboxytetramethylrhodamine (TAMRA) was used as a drug model, and galactose (Gal) recognized by liver parenchymal cells was used as a homing device. TAMRA and galactose were attached to biotin (Bio) through a triethyleneglycol (TEG) spacer group to give Bio-TEG-TAMRA conjugate and Bio-TEG-Gal conjugate, respectively. Confocal laser scanning microscopic studies suggest that the complexes prepared by mixing Bio-TEG-Gal conjugate and fluorescein isothiocyanate (FITC)-labeled Av (feed molar ratio 4:1), and mixing Bio-TEG-Gal conjugate, Bio-TEG-TAMRA conjugate and FITC-labeled Av are internalized into the hepatoma cells through a receptor-mediated endocytosis mechanism.

Preparation of a biodegradable matrix through polyion complex formation by mixing polylactide-based microspheres having oppositely charged surfaces.

The aggregation of polyions into microsphere (MS) complexes was studied as a preparative method for the construction of a biodegradable matrix. Aqueous suspensions of polylactide (PLA)-based MSs with positively and negatively charged surfaces, MS(K(3)(4+)-PLA) and MS(E(3)(4-)-PLA), respectively, immediately formed aggregates when mixed. The effects of the stoichiometry of the charged groups on the surfaces of the MSs and the ionic strength of the medium on aggregate formation, as well as the degradation behavior of the polyion complex (PIC) matrix over time, were investigated.

Multistep fluorescence resonance energy transfer in sequential chromophore array constructed on oligo-DNA assemblies.

Sequential arrays of chromophores at regulated distances were constructed on a noncovalent DNA molecular assembly system in aqueous media. Photoinduced fluorescence resonance energy transfer (FRET) behaviors were then observed. We designed a number of chromophore/oligo-DNA conjugates with varying sequences. The chromophores eosin (Eo), TexasRed (TR), and tetramethylrhodamine (Rho) were employed as the energy donor, acceptor, and mediator, respectively, based on overlapping excitation and emission spectra. The chromophores were attached via aminolinkers to the 5'-terminals of 10mer oligo-DNAs consisting of AT rich sequences. The arrangement of Eo-Rho or Rho-TR with 10-residue (1 pitch of duplex) distances was ensured by duplex formation of the conjugates with a 20mer matrix oligo-DNA composed of complementary sequences to the conjugates. Single-step FRET from Eo to Rho and from Rho to TR was confirmed on the duplex. The three chromophore conjugates were then mixed with longer matrix oligo-DNAs (30 or 40mer) consisting of complementary sequences to the conjugates, producing Eo-(Rho)(n)-TR (n = 1 or 2) arrays with 10-residue distances. Multistep FRET from Eo to TR through the Rho mediator(s) was observed on the molecular assemblies. This photoenergy transmission system offers a good model for a photoenergy transmission system mimicking photosynthetic systems.

Synthesis of poly(L-lactide) end-capped with lactose residue.

The synthesis of poly(L-lactide) (polyLA) end-capped with lactose residue was studied from the standpoint of development of a new bioabsorbable material. After the hydroxyl group of t-butoxycarbonyl(Boc)-aminoethanol was converted to Boc-aminoethanol-OK by using potassium/naphthalene, L-lactide was polymerized in tetrahydrofuran using Boc-aminoethanol-OK as an initiator at room temperature to prepare polyLA-NHBoc. Subsequently, the removal of the Boc group in terminal Boc-aminoethanol residue was performed by treatment of formic acid to obtain the amino group end-capped polyLA (polyLA-NH(2)) as a reactive polyLA derivative. The coupling reactions of lactose with polyLA-NH(2) were investigated by two methods; the synthetic method through reductive amination of lactose with polyLA-NH(2) in the presence of sodium cyanoborohydride as a reducing agent did not give high degree of substitution of end-capped lactose residue per polyLA molecule, whereas the synthetic method through the ester interchange reaction of lactonolactone with polyLA-NH(2) gave Lac-polyLA perfectly end-capped with lactose residue.