0.2mL 8_Strip PCR Tube Caps
- Known as:
- 0.2mL 8_Strip PCR test kit Tube Caps
- Catalog number:
- C-028-O
- Product Quantity:
- 125 ea
- Category:
- -
- Supplier:
- Bioner
- Gene target:
- 0.2mL 8_Strip PCR Tube Caps
Related genes to: 0.2mL 8_Strip PCR Tube Caps
- Gene:
- CAPS NIH gene
- Name:
- calcyphosine
- Previous symbol:
- -
- Synonyms:
- CAPS1, MGC126562
- Chromosome:
- 19p13.3
- Locus Type:
- gene with protein product
- Date approved:
- 1990-05-31
- Date modifiied:
- 2016-07-18
Related products to: 0.2mL 8_Strip PCR Tube Caps
Related articles to: 0.2mL 8_Strip PCR Tube Caps
- - Source: PubMed
Publication date: 2026/06/06
Essien Utibe RByhoff Elena - Microneedle arrays (MNAs) is a rapidly emerging technology with broad biomedical applications in drug delivery and biosensing. With sub-millimeter dimensions and periodicity, MNAs possess geometries nearly ideal for biomedical devices operating within the terahertz (THz) spectral window. Because chirality is crucial to the function of deposited drugs and surrounding tissues, realizing chiroptical resonances within MNAs could impart new capabilities to microneedle-based technologies. However, methodologies for fabricating chiral MNAs are largely unknown and their importance remains largerly unrecognized. Here, we present a pathway to arrays of chiral microneedles (ARCHIMs) that exhibit strong and predictable chiroptical resonances in the THz range. These chiroplasmonic microneedles were prepared by glancing angle deposition of two sequential gold layers. ARCHIMs with thin, non-centrosymmetric caps on each needle exhibit strong chiral plasmonic modes characterized by distinct THz circular dichroism (TCD) bands and polarization rotations as large as 5 degrees. To emulate chiral drugs and biologics, we coated the ARCHIMs with L- and D-cystine crystals. We found that chiral phonons in the biocrystals resonate with chiral plasmons in the microneedles; their coupling induces handedness-dependent shifts in the TCD spectra. This photonic effect was quantitatively described using a modified temporal coupled mode theory that incorporates polarization-dependent resonator parameters. Our findings demonstrate that ARCHIMs provide an effective, tunable, and scalable platform for exploiting chiral light-matter interactions, opening new opportunities in TCD sensing, chiral diagnostics, chiral phonon detection and THz photonics. - Source: PubMed
Publication date: 2026/06/06
Lee Sang HyunJung Hong JuKim JohnPark Bum Chulda Silva Caio V C Rde Moura André FKotov Nicholas A - The autoimmune nodopathy affecting the node of Ranvier was formerly classified within the spectrum of chronic inflammatory demyelinating polyradiculoneuropathy. However, as a result of comprehensive pathological and immunological investigations conducted in recent years, it has increasingly been recognized as a distinct clinical entity. To date, there have been no reported cases linking autoimmune nodopathy at the node of Ranvier with anti-CNTN2 antibodies. This paper presents a case study demonstrating such an association, detailing the clinical and electrophysiological features, and thereby contributing to the global understanding and recognition of this condition. - Source: PubMed
Publication date: 2026/06/05
Zeng XiaoxiaHu JuanjuanLi KeGan ZhijiQi Xueliang - In mammalian cells, the mRNA 5' caps possess important functions such as efficient protein translation and evasion of innate immune surveillance. The primary cap structure, mGppp- or Cap-0, is generated by three enzymatic activities in tandem - RNA 5' triphosphatase (TPase), mRNA guanylyltransferase (GTase), and mRNA cap N7-guanine methyltransferase (N7-MTase). In large DNA viruses such as poxviruses and giant viruses, the three activities are consolidated into a multifunctional protein with distinct structural domains. Although widely used in mRNA synthesis in vitro, detailed mechanistic studies of these RNA capping enzymes have been limited. Here, we performed kinetic studies on Vaccinia virus (VCE) and Faustovirus (FCE) capping enzymes using a high-throughput capillary electrophoresis assay that simultaneously quantifies all substrates and products in the three reactions. We found that GTase is the rate-limiting step of both capping enzymes; however, in VCE, the TPase is much faster than N7-MTase, whereas the rate of the two activities are largely comparable in FCE. We further show that the GTase of VCE is slower in the forward direction than the reverse under isolated single turnover conditions, and that the presence of N7-MTase activity increased the observed rate constant of the GTase reaction under multiple turnover conditions. In contrast, the GTase of FCE is slightly faster in the forward direction and the N7-MTase activity does not influence the FCE GTase reaction kinetics. Global simulation of full reactions across reaction conditions further identifies the rate-limiting steps of the individual enzyme activities and provides a framework to describe their interdependence. - Source: PubMed
Publication date: 2026/06/04
Molé ChristaPan JuanKneller DanielEscobar Edwin EHanneman AndyChan S Hong - Internal waves are energetic and ubiquitous in the ocean and their interactions with submarine topography could drive sediment resuspension and reshape seafloor substrate. However, the mechanisms governing these interactions are largely unknown. Here, using observational and reanalysis data at Pacific deep-sea seamounts, we show how near-inertial internal waves (NIWs) may affect substrate variability via interactions with seamounts. Taylor caps with anticyclonic vorticity generated above the seamounts can act as a "chimney" that focuses NIW energy. The NIWs can further undergo reflection at the summits and generate strong bottom currents to erode sediments. As wind energy input to NIWs increases with latitude, this process could contribute to the removal of sediments at seamount summits further north than 20°N, exposing the rock outcrops needed for biogenic structuring species and thus boosting species richness. Given that Taylor caps occur at ~93% of the global seamounts, our findings suggest a wave-topography interaction that could shape the substrate and enrich the biodiversity in the deep ocean. - Source: PubMed
Publication date: 2026/06/05
Xie XiaohuiQu LixinLi MingThomas LeifChen DakeZhou LeiZhang DongshengWang JiannanPan HaoShen ChengchengRen Wenting