Impact of long-term parental exposure to Tamiflu metabolites on the development medaka offspring (Oryzias latipes).

Despite the widespread use of the antiviral drug, Tamiflu®, little is known about the long-term toxic effects of drug or its metabolites in an aquatic ecosystem. This study integrated epidemiological and ecotoxicological methods to determine environmentally relevant concentrations of Tamiflu. A model based on the species medaka (Oryzias latipes) was then used to determine the health status and reproductivity of adults exposed to the drug as well as the embryonic development of offspring. The proposed ecotoxicological model was also used to quantitatively and qualitatively evaluate the toxicodynamic parameters related to egg production, hatchability, and development. Our results revealed that at an environmentally relevant exposure, Tamiflu and its metabolites had no adverse effects on growth, survival, or fecundity of adult medaka. Nonetheless, we observed a reduction in hatchability under exposure to 300 µg L-1 and a reduction in body length under exposure exceeding 90 µg L-1. Under exposure to 300 µg L-1, the estimated spawning time to reach 50% of the maximum percentage of cumulative egg production (ET50) far exceeded that of the control group (without exposure to Tamiflu). We also observed a ∼ 3-fold decrease in maximum egg hatching (Emax). Based on an integrated epidemiological and ecotoxicological model, predictions of environmental concentrations of Tamiflu and its metabolites revealed that the influenza subtypes associated with increases in environmental concentrations: A(H3N2) > A(H1N1) > type B (in order of their effects). We also determined that A(H3N2) posed a potential risk to hatchability and development. Note however, the environmental concentrations of Tamiflu and its metabolites in most countries are lower than the effect concentrations derived in this study, indicating no hazards for aquatic environments. We recommend the use of hatchability and embryonic development as indicators in assessing the effects of long-term parental exposure to Tamiflu metabolites.

Osteogenic Surface Modification Based on Functionalized Poly-P-Xylylene Coating.

The biotechnology to immobilize biomolecules on material surfaces has been developed vigorously due to its high potentials in medical applications. In this study, a simple and effective method was designed to immobilize biomolecules via amine-N-hydroxysuccinimide (NHS) ester conjugation reaction using functionalized poly-p-xylylene coating on material surfaces. The NHS ester functionalized coating is synthesized via chemical vapor deposition, a facile and solvent-less method, creating a surface which is ready to perform a one-step conjugation reaction. Bone morphogenetic protein 2 (BMP-2) is immobilized onto material surfaces by this coating method, forming an osteogenic environment. The immobilization process is controlled at a low temperature which does not damage proteins. This modified surface induces differentiation of preosteoblast into osteoblast, manifested by alkaline phosphatase (ALP) activity assay, Alizarin Red S (ARS) staining and the expression of osteogenic gene markers, Alpl and Bglap3. With this coating technology, immobilization of growth factors onto material surface can be achieved more simply and more effectively.

Evenly distributed thin-film Ag coating on stainless plate by tricomponent Ag/silicate/PU with antimicrobial and biocompatible properties.

A tricomponent nanohybrid dispersion in water comprising silver nanoparticles (AgNP), nanometer-thick silicate platelets (NSP), and water-based polyurethane (PU) was developed for surface coating on orthopedic metal plates. The previously developed AgNP-on-NSP nanohybrid was homogeneously blended into a selected waterborne PU dispersion at varied weight ratios from 1/0.1 to 1/10 (w/w). PU was used to adhere the Ag nanohybrid to the metal surface. The resultant dispersions were analyzed and found to contain AgNP 2-18 nm in diameter and characterized by using UV absorption and TEM micrograph. The subsequent coating of AgNP/NSP-PU dispersion generated a film of 1.5 µm thickness on the metal plate surface, further characterized by an energy dispersive spectroscope (EDS) to show the homogeneous distribution of Ag, Si, and C elements on the metal plates. The surface antimicrobial efficacy was proven for the coating composition of AgNP/NSP to PU ranging from 1/1 to 1/5 by weight ratio but irrelevant to the thickness of the coated materials. The metal plate coated with the high Ag content at 1/1 (w/w) ratio was shown to have very low cytotoxicity toward the contacted mammal fibroblasts. Overall, the optimized tricomponent Ag/silicate/PU in water dispersion from 1/2 to 1/3 (w/w) could generate a stable film on a metal surface exhibiting both antimicrobial and biocompatible properties. The facile coating technique of the AgNP/NSP in waterborne PU is proven to be viable for fabricating infection- and cytotoxicity-free medical devices.

Compatibility balanced antibacterial modification based on vapor-deposited parylene coatings for biomaterials.

Advanced antibacterial surfaces are designed based on covalently attached antibacterial agents, avoiding potential side effects associated with overdosed or eluted agents. The technique is widely applicable regardless of the underlying substrate material. In addition, antibacterial surfaces are effective against the early stages of bacterial adhesion and can significantly reduce the formation of biofilm, without compromising biocompatibility. Here, this concept was realized by employing a benzoyl-functionalized parylene coating. The antibacterial agent chlorhexidine was used as a proof of concept. Chlorhexidine was immobilized by reaction with photoactivated benzoyl-functionalized surfaces, including titanium alloy, stainless steel, polyether ether ketone, polymethyl methacrylate, and polystyrene. A low concentration of chlorhexidine (1.4 ± 0.08 nmol cm-2) covalently bound to surfaces rendered them sufficiently resistant to an Enterobacter cloacae inoculum and its adherent biofilm. Compared to unmodified surfaces, up to a 30-fold reduction in bacterial attachment was achieved with this coating technology. The immobilization of chlorhexidine was verified with infrared reflection absorption spectroscopy (IRRAS) and X-ray photoelectron spectroscopy (XPS), and a leaching test was performed to confirm that the chlorhexidine molecules were not dislodged. Cell compatibility was examined by culturing fibroblasts and osteoblasts on the modified surfaces, revealing greater than 93% cell viability. This coating technology may be broadly applicable for a wide range of other antibacterial agents and allow the design of new biomaterials.

Identification of genes differentially expressed during the growth of Bambusa oldhamii.

Bamboos are ecologically and economically important grasses, and are distinguished by their rapid growth. To identify genes associated with bamboo growth, PCR-based mRNA differential display was used to clone genes that were differentially expressed in various tissues of bamboo (Bambusa oldhamii) shoots at different growth stages. In total, 260 different cDNA sequences were obtained. These genes displayed complex expression profiles across the different tissues and growth stages as revealed by a cDNA microarray analysis. Notable among them were genes that were temporally up-regulated or down-regulated in the internode-containing region of rapidly elongating shoots. These genes might participate in the rapid elongation of the bamboo culm. Of the 36 up-regulated and 46 down-regulated genes, 16 genes and 8 genes, respectively, were predicted to encode hypothetical proteins or were unknown sequences. Aside from these, genes involved in hormonal signaling and homeostasis, stress responses, peptide processing and signaling and lignin biosynthesis composed most of the up-regulated genes; genes involved in DNA replication, nucleic acid binding and signal transduction were highly represented among the down-regulated genes. These results suggested that genes associated with plant hormonal signaling and homeostasis, peptide signaling, reactive oxygen species signaling and homeostasis, several stress-related genes and a monocot-specific unknown gene, BoMSP41, play important roles in the elongation of bamboo internodes. Multiple signaling pathways might form a complex interconnected network that controls the rapid growth of this giant grass.