Poplar catkin: A natural biomaterial for highly specific and efficient enrichment of sialoglycopeptides

Sialic acids as terminal entities of larger glycans linked to proteins and lipids are involved in multiple different pathological and physiological processes. Structural characterisation of sialoglycoconjugates is required to understand their biological function. However, a comprehensive sialylation analysis of sialoglycoconjugates has remained challenges. In this study, we employ a natural biomaterial, poplar catkin derived from white poplar tree (Populus tomentosa Carr.), to develop a novel capturing microtip for selective and efficient enrichment of sialoglycopeptides, without losses of sialic acid residues and water molecules from sialoglycopeptides. Scanning electron microscopy and Fourier-transform infrared spectroscopy analysis, along with Mäule and Wiesner staining assays, indicated that the main components on the outer layer of the poplar catkin are syringyl and guaiacyl lignins which play a key role in enriching sialoglycopeptides from complex peptide mixture.     

A Trifunctional,Modular Biomaterial Coating: Nonadhesive to Bacteria,Chlorhexidine‐Releasing and Tissue‐Integrating

Various potential anti‐infection strategies can be thought of for biomaterial implants and devices. Permanent, tissue‐integrated implants such as artificial joint prostheses require a different anti‐infection strategy than, for instance, removable urinary catheters. The different requirements set to biomaterials implants and devices in different clinical applications call for tailor‐made strategies. Here, a modular coating‐concept for biomaterials is reported, which in its full, trifunctional form comprises nonadhesiveness to bacteria and antimicrobial release, combined with enhanced tissue integration characteristics. Nonadhesiveness to proteins and bacteria is accomplished by a hydrophilic brush coating (Vitrostealth). The antimicrobial release module is constituted by a chlorhexidine releasing poly(ethylene glycol) diacrylamide based‐coating that continues to release its antimicrobial content also when underneath the nonadhesive top‐coating. The third module, enhancing tissue integration, is realized by the incorporation of the penta‐peptide Glycine‐Arginine‐Glycine‐Aspartic acid‐Serine (GRGDS) within the nonadhesive top‐coating. Modules function in concert or independently of each other. Specifically, tissue integration by the GRGDS‐module does not affect the nonadhesiveness of the Vitrostealth‐module toward bovine serum albumin and Staphylococcus aureus , while the antimicrobial release module does not affect tissue‐integration by the GRGDS‐module. Uniquely, using this modular system, tailor‐made anti‐infection strategies can thus readily be made for biomaterials in different clinical applications.

     

The study of the structure and bioactivity of the B2O3 • Na2O • P2O5 system

In this study, we have investigated calcium and silicate‐free samples over a wide compositional range in the xB₂O₃·30 Na₂O·(70−x)P₂O₅ system, with 0 ≤ x ≤ 70 mol%, in order to determine the influence of the chemical composition on their structure and bioactive response in simulated body fluid. Information related to the chemical structures present in the network was obtained by means of Raman and infrared spectroscopy. For samples containing small amounts of P₂O₅, boron structures are preponderant. Upon increasing the phosphorus content, the samples' network is based on phosphate chains linked by boron groups through ‘P–O–B’ bridges. For high concentration of P₂O₅, the Q³ units form three‐dimensional network, whereas Q² units assist the chain formation. Regarding the in vitro assessment of bioactivity, the clear print of PO₄ asymmetric bending vibrations of apatite‐like layer in the 540–680 cm⁻¹ spectral domain, the scanning electron micrographs and energy dispersive x‐ray analysis spectra demonstrate that the studied borophosphate samples exhibit good bioactive response only for certain chemical compositions. More exactly, the highest bioactivity is obtained for 30% and 20% B₂O₃ (mol%) after 3 and 11 days of immersion, respectively. Therefore, the samples with 20–30 mol% boron content are valuable candidates that can be used as materials for tissue engineering applications. Copyright © 2013 John Wiley & Sons, Ltd.     

Chemical preparation and characterization of new biodegradable aliphatic polyesters end‐capped with diverse steroidal moieties

Novel metal complexes with a single catalytic site and less transesterification seem to provide alternative efficient synthetic approaches to preparing new biodegradable and biologically responsive materials with well‐defined structures. In this study, we rationally designed a new category of aluminum metal complexes bearing a bulky Salen ligand and diverse steroidal alkoxy moieties to synthesize novel biodegradable aliphatic polyesters end‐capped with steroidal building blocks. At first, three new aluminum metal complexes ( 9 – 11 ) were synthesized with good yields of 80–90%, bearing cholesterol and diosgenin derivatives as functional alkoxy moieties. By means of nuclear magnetic resonance (NMR) spectrometry, matrix‐assisted laser desorption/ionization Fourier transform mass spectrometry (MALDI–FTMS), and Fourier transform infrared spectrometry, the molecular structures of 9 – 11 were characterized. Furthermore, new biodegradable aliphatic polyesters, poly(ε‐caprolactone) and poly(δ‐valerolactone) end‐capped with diverse steroidal moieties, were synthesized through the ring‐opening polymerization of ε‐caprolactone and δ‐valerolactone catalyzed by these new metal complexes under 100 °C in toluene, and they were also characterized by gel permeation chromatography, NMR, MALDI–FTMS, differential scanning calorimetry, and thermogravimetric analysis. Very narrow molecular weight distributions were revealed for these new polymer products, and their thermal crystallization and stability strongly depended on the degree of polymerization of the polyester building blocks and the distinct steroidal moieties. Because of the nature of the steroidal moieties, these biodegradable polymers may pave a path to new possibilities as potential biomaterials. © 2006 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 44: 2045–2058, 2006     

Mechanisms for Imparting Conductivity to Nonconductive Polymeric Biomaterials

Traditionally, conductive materials for electrodes are based on high modulus metals or alloys. Development of bioelectrodes that mimic the mechanical properties of the soft, low modulus tissues in which they are implanted is a rapidly expanding field of research. Many polymers exist that more closely match tissue mechanics than metals; however, the majority do not conduct charge. Integrating conductive properties via incorporation of metals and other conductors into nonconductive polymers is a successful approach to producing polymers that can be used in electrical interfacing devices. When combining conductive materials with nonconductive polymer matrices, there is often a tradeoff between the electrical and mechanical properties. This review analyzes the advantages and disadvantages of approaches involving coating or layer formation, composite formation via dispersion of conductive inclusions through polymer matrices, and in situ growth of a conductive network within polymers.

     

丝素蛋白3D打印在生物医学领域中的应用

增材制造,也称为三维(3D)打印,正推动制造、工程、医学等领域的全面创新升级。3D打印技术由于能够个性化定制生物的复杂3D微结构,构建仿生的功能化活组织或人工器官,近十年来在生物医学领域中取得了长足的发展。丝素蛋白(SF)是一种来源丰富、生物可降解、力学性能优良、细胞相容性极佳的天然有机高分子,为3D打印墨水的设计提供了一种有前景的选择。然而,作为结构蛋白,单一组分的SF具有的生理功能有限,且其经过打印后的稳定性较差,限制了SF在3D打印以及生物医药领域中的进一步发展。为此,研究人员通过化学改性技术和先进3D打印技术相结合,使得改性后的SF能够更适用于3D打印,并发展成为一种具有应用价值的生物材料。本文综述了SF的结构特征、SF的化学修饰策略、打印墨水的制备策略以及3D打印SF材料在生物医学领域的最新应用进展,并展望了3D打印SF生物材料的未来发展趋势,为其在更广阔领域的应用提供一定的借鉴。     

Synthesis and characterization of amphiphilic antibacterial copolymers

Macromolecule antimicrobials have been explored in foundational research and practical application due to their potential merit for reducing the residual toxicity, increasing their efficiency, selectivity, and prolonging the lifetime of the antimicrobial material. In this work, the quaternized poly(styrene)‐b‐poly(DMAEMA) diblock polymers are synthesized by reversible addition‐fragmentation chain transfer polymerization (RAFT). The minimum inhibitory concentration (MIC) evaluation and optical density (OD) method demonstrated that the amphiphilic antibacterial biomaterials have exceptional antibacterial properties. The amphiphilic polycation has an admirable antibacterial property, and these quaternized diblocks are potent biocides and nonhemolytic. The relationship between the structure and activity is discussed with respect to molecular weight of the diblocks and bacteria structural dependence. Copyright © 2011 John Wiley & Sons, Ltd.     

Multicomponent supramolecular thermoplastic elastomer with peptide‐modified nanofibers

Bioactive nanofibers present a promising synthetic niche for in vivo applications due to their morphological and functional resemblance to the extracellular matrix. Potentially interesting nanofibers are constructed from the hard‐segment regimes in well‐defined thermoplastic elastomers (TPEs). The supramolecular interactions between these hard segments cause physical crosslinking by the formation of nanofibers and provide excellent mechanical properties. Here, we make use of a new class of biocompatible supramolecular TPEs, in which both the formation of the main chain and the hard block is based on multiple hydrogen‐bonding interactions. A self‐assembly process is explored to arrive at well‐defined peptide‐modified nanofibers embedded in a biocompatible soft matrix. Crucial for the success in the synthetic design is the use of an exact match between the molecular recognition units of the peptide and the supramolecular unit that takes care of forming the supramolecular nanofibers of the TPE. Evidence for the strong anchoring of the modified peptides in the hard‐segment nanofibers of the supramolecular TPE is provided by simple extraction experiments. © 2011 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem, 2011