Phosphorylation of alginate: synthesis, characterization, and evaluation of in vitro mineralization capacity.

Phosphorylation of alginate was achieved using a heterogeneous urea/phosphate reaction. The degree and stereoselectivity of phosphorylation as well as the effects on the physical properties of the polysaccharide were investigated by Fourier transform infrared (FTIR) and nuclear magnetic resonance (NMR) spectroscopies, inductively coupled plasma optical-emission spectroscopy (ICP-OES), and size exclusion chromatography (SEC). Multidimensional NMR studies of the phosporylated alginate revealed that phosphorylation of the M residues occurred predominantly at the C3 (equatorial) carbon of the polysaccharide ring. In addition, a more comprehensive assignment of the (1)H NMR spectrum of alginate, compared with those previously reported in the literature, is provided here. Hydrogel materials were formed from ionically cross-linked blends of phosphorylated alginate and alginate. These blended hydrogels showed an enhanced resistance to degradation by chelating agents compared with cross-linked alginate hydrogels and a reduction in their mineralization potential.

Do We Need to Design Course-Based Undergraduate Research Experiences for Authenticity?

The recent push for more authentic teaching and learning in science, technology, engineering, and mathematics indicates a shared agreement that undergraduates require greater exposure to professional practices. There is considerable variation, however, in how "authentic" science education is defined. In this paper we present our definition of authenticity as it applies to an "authentic" large-scale undergraduate research experience (ALURE); we also look to the literature and the student voice for alternate perceptions around this concept. A metareview of science education literature confirmed the inconsistency in definitions and application of the notion of authentic science education. An exploration of how authenticity was explained in 604 reflections from ALURE and traditional laboratory students revealed contrasting and surprising notions and experiences of authenticity. We consider the student experience in terms of alignment with 1) the intent of our designed curriculum and 2) the literature definitions of authentic science education. These findings contribute to the conversation surrounding authenticity in science education. They suggest two things: 1) educational experiences can have significant authenticity for the participants, even when there is no purposeful design for authentic practice, and 2) the continuing discussion of and design for authenticity in UREs may be redundant.

A novel strategy for preparing mechanically robust ionically cross-linked alginate hydrogels.

The properties of alginate films modified using two cross-linker ions (Ca(2+) and Ba(2+)), comparing two separate cross-linking techniques (the traditional immersion (IM) method and a new strategy in a pressure-assisted diffusion (PD) method), are evaluated. This was achieved through measuring metal ion content, water uptake and film stability in an ionic solution ([Ca(2+)] = 2 mM). Characterization of the internal structure and mechanical properties of hydrated films were established by cryogenic scanning electron microscopy and tensile testing, respectively. It was found that gels formed by the PD technique possessed greater stability and did not exhibit any delamination after 21 day immersion as compared to gels formed by the IM technique. The Ba(2+) cross-linked gels possessed significantly higher cross-linking density as reflected in lower water content, a more dense internal structure and higher Young's modulus compared to Ca(2+) cross-linked gels. For the Ca(2+) cross-linked gels, a large improvement in the mechanical properties was observed in gels produced by the PD technique and this was attributed to thicker pore walls observed within the hydrogel structure. In contrast, for the Ba(2+) cross-linked gels, the PD technique resulted in gels that had lower tensile strength and strain energy density and this was attributed to phase separation and larger macropores in this gel.

Development of a multiplexed bead-based assay for detection of DNA methylation in cancer-related genes.

Herein we report a method for the detection of methylated CpG dinucleotides located within CpG islands in genomic DNA using multiplexed bead-based assays and standard flow cytometry instrumentation. Four CpG "clusters" were identified in the TFPI2 and SPARC CpG islands whose methylation status was highly correlated with the incidence of invasive cervical cancer in our previous studies. Eight probes in total were designed for both the methylated and unmethylated forms of each cluster and attached to different fluorescently-encoded organosilica bead sets. Probe design was investigated by changing either the length of probes whilst keeping the melting temperature constant, or changing the melting temperature and keeping the probe length constant. Asymmetric polymerase chain reaction (PCR) methods designed without methylation-specific primers were used to prepare fluorescently-labelled targets based on bisulfite-converted genomic DNA. After investigating the specificity of the probes in a model system using fluorescently-labelled synthetic oligonucleotides, cancer cell-line DNA was analysed and the constant length probe design facilitated the correct genotyping of all clusters with respect to negative controls.

Encapsulation of a glycosaminoglycan in hydroxyapatite/alginate capsules.

The development of suitable vehicles for the delivery of growth-inducing factors to fracture sites is a challenging area of bone repair. Bone-specific glycosaminoglycan molecules are of particular interest because of their high stability and proven effect on bone growth. Calcium alginate capsules are popular as delivery vehicles because of their low immunogenic response; they offer a versatile route that enables the controlled release of heparin (a member of the glycosaminoglycan family). In this study, hydroxyapatite (HA)/alginate composite capsules are explored as novel drug delivery vehicles for heparin, using both medium- and low-viscosity alginates. The composition, structure, and stability of the capsules are fully characterized and correlated to the release of heparin in vitro. Heparin is found to associate both with the alginate matrix through polymeric flocculation and also with the HA crystals in the composite beads. The mechanism by which heparin is released is dictated by the stability of the capsule in a particular release media and by the composition of the capsule. The use of medium-viscosity alginate is advantageous with respect to both drug loading and prolonging the release. The inclusion of HA increases the encapsulation efficiency, but because of its destabilizing effect to the alginate hydrogel matrix, it also increases the rate of heparin release. The bioactivity of heparin is fully retained throughout the assembly and release processes.

Modification and optimization of organosilica microspheres for peptide synthesis and microsphere-based immunoassays.

A new generation of optically encoded organosilica microspheres, suitable for both solid phase synthesis and multiplexed microsphere-based assays, has recently been described. One of the challenges of producing this type of dual-purpose solid support is that the particles must maintain their morphology as well as their encoding during exposure to the solvents used for solid phase synthesis. In this article, organosilica microspheres are subjected to ammonia treatment methods for enhancing the condensation of the silica matrix and their subsequent resilience toward organic solvents and peptide synthesis reagents is described. The instability of the untreated supports toward organic synthesis reagents was found to be associated with the swelling and permeability of these microspheres in organic solvents. Post-synthesis ammonia treatment resulted in reduced permeability, as demonstrated by dye uptake studies. The treated microspheres exhibited enhanced stability against organic synthesis conditions and were characterized via a variety of techniques including electron microscopy, (29)Si-nuclear magnetic resonance (NMR) and optical microscopy. The ammonia-treated supports were subjected to an Fmoc peptide synthesis procedure and successfully applied in a model microsphere-based flow cytometric immunoassay.

Synthesis and characterization of alginate/poly-L-ornithine/alginate microcapsules for local immunosuppression.

Alginate/poly-L-ornithine/alginate (APA) coherent microencapsulation, which provides an immunoselective and highly biocompatible membrane, creates a viable option for cellular or tissue transplantation. This study explored the potential of incorporating immunosuppressive drugs onto the capsule surface to provide local immunosuppression in addition to immunoisolation. A thorough investigation has been conducted to optimize and characterize alginate biotinylation via carbodiimide chemistry by a 4'-hydroxyazobenzene-2-carboxylic acid (HABA) based assay and by ATR-FTIR, H-NMR and XPS. To minimize the formation of by-product, a theoretical 40% activation of the carboxylic group on the alginate was employed to manufacture an optimal modification of approximately 10% biotinylated alginate. Confocal fluorescence microscopy was used to assess the conjugation of streptavidin and assembly of antibodies on the microcapsules. Local immunosuppressive capacity was assimilated on the APA microcapsules by binding of anti-tumour necrosis factor-alpha (TNF-alpha) antibodies via streptavidin-biotin conjugation, shown from the clear reduction of TNF-alpha in in-vitro medium.

Interactions between alginate and chitosan biopolymers characterized using FTIR and XPS.

This study investigates alginate-chitosan polyelectrolyte complexes (PECs) in the form of a film, a precipitate, as well as a layer-by-layer (LbL) assembly. The focus of this study is to fully characterize, using the complementary techniques of Fourier transform infrared (FTIR) spectroscopy and X-ray photoelectron spectroscopy (XPS) in combination with solution stability evaluation, the interactions between alginate and chitosan in the PECs. In the FTIR spectra, no significant change in the band position of the two carbonyl vibrations from alginate occurs upon interaction with different ionic species. However, protonation of the carboxylate group causes a new band to appear at 1710 cm(-1), as anticipated. Partial protonation of the amine group of chitosan causes the appearance of one new band ( approximately 1530 cm(-1)) due to one of the -NH3+ vibrational modes (the other mode overlaps the amide I band). Importantly, the position of the two main bands in the spectral region of interest in partly protonated chitosan films is not dependent on the extent of protonation. XPS N 1s narrow scans can, however, be used to assess the degree of amine protonation. In our alginate-chitosan film, precipitate, and LbL assembly, the bands observed in the FTIR correspond to the species -COO- and -NH3+, but their position is not different from each of the single components. Thus, the conclusion of the study is that FTIR cannot be used directly to identify the presence of PECs. However, in combination with XPS (survey and narrow N 1s scans) and solution stability evaluation, a more complete description of the structure can be obtained. This conclusion challenges the assignment of FTIR spectra in the literature.