Surface Treatment on Physical Properties and Biocompatibility of Orthodontic Power Chains.

The conventional orthodontic power chain, often composed of polymer materials, has drawbacks such as a reduction of elasticity owing to water absorption as well as surface discoloration and staining resulting from food or beverages consumed by the patient. The goal of this study was to develop a surface treatment (nanoimprinting) for orthodontic power chains and to alleviate their shortcomings. A concave template (anodic alumina) was manufactured by anodization process using pure aluminum substrate by employing the nanoimprinting process. Convex nanopillars were fabricated on the surface of orthodontic power chains, resulting in surface treatment. Distinct parameters of the nanoimprinting process (e.g., imprinting temperature, imprinting pressure, imprinting time, and demolding temperature) were used to fabricate nanopillars on the surface of orthodontic power chains. The results of this study showed that the contact angle of the power chains became larger after surface treatment. In addition, the power chains changed from hydrophilic to hydrophobic. The power chain before surface treatment without water absorption had a water absorption rate of approximately 4%, whereas a modified chain had a water absorption rate of approximately 2%-4%. Furthermore, the color adhesion of the orthodontic power chains after surface modification was less than that before surface modification.

Cloning and sequencing of full-length cDNA of classical swine fever virus LPC strain.

The cDNAs of classical swine fever virus (LPC vaccine strain) were cloned by transcriptase-polymerase chain reaction, and their nucleotide sequences were determined. In this work, we obtained the sequence information of the 786 bases of the 5'-terminal region, 6049 bases of the middle region, and 1648 bases of the 3'-terminal region. Taking our previous results and present data together, the entire genomic sequence of LPC strain was completed (12344 nucleotides in length). The genome of LPC has a large open reading frame that can encode a polypetide of 3897 amino acids, and are flanked by untranslated regions (UTR), 373 bases at the 5'-end and 278 bases at the 3'-end. Phylogenetic analysis based on genomic sequences of several viruses suggested that the LPC strain is closer to Chinese, Riems, HCLV, Alfort/187, Brescia, and Alfort strains in order. After further analysis, we found that an insertion of 13 nucleotides, TTT(C/T)CTTTTTTTT, in the 3'-UTR of LPC, Chinese, and HCLV strains. Immediately downstream to the 13 nucleotides, a unique sequence of LPC consisting of 28 thymidine was observed.