ABSTRACT
In this work, an upconversion luminescence (UCL) nanosensor for fast detection of ferric ion (Fe3+) and phosphate ion (Pi) is developed based on the inner-filter effect (IFE) between NaYF4:Yb/Er upconversion nanoparticles (UCNPs) and Fe3+-hypocrellin B (HB) complex. Fe3+-HB complex has strong absorption band (450-650 nm), which overlaps with the green emission peak of UCNPs at 545 nm. By adding Fe3+ and Pi, the UCNPs-HB system produces the red-shift change of absorption spectrum, which leads to the "on-off-on" process of IFE. So, with the specific recognition ability of HB for Fe3+ and the competitive complexation of Pi for Fe3+, the proposed nanosensor utilizes the UCL change to achieve the detection of the targets. For the detections of Fe3+, the linear range is 10-600 µM with a limit of detection (LOD) of 2.62 µM, and for Pi, the linear range is 5-100 µM with a LOD of 1.25 µM. The results for selectivity, precision, and recovery test are also satisfactory. Furthermore, the real sample detection shows that the proposed nanaosensor has a great potential in environmental and biological systems. An upconversion luminescence (UCL) nanosensor based on the inner-filter effect (IFE) between upconversion nanoparticles (UCNPs) and Fe3+-hypocrellin B (HB) complex for the detection of Fe3+ and phosphate ion has been proposed, which is promising to be a convenient and sensitive assay for monitoring Fe3+ and phosphate ion in different environments and biological systems.
ABSTRACT
Based on the mechanism of luminescence resonance energy transfer (LRET) and using a special single strand DNA as the recognition element, a portable paper-based sensor for the accurate detection of total heavy rare-earth ions (mainly Gd3+, Tb3+ and Dy3+) concentration was proposed. The RNA cleaving-DNAzyme should recognize rare-earth ions to cleave RNA on DNA duplexes linking UCNPs and AuNPs, causing UCNPs and AuNPs to approach each other, inducing LRET, which attenuated the green upconversion luminescence (UCL) triggered by the 980 nm laser. UCL was captured by a charge-coupled device (CCD) image sensor and processed with the red-green-blue (RGB) image to quantitatively analyze heavy rare-earth ions in the samples. In the range of 5-50 µmol·L-1, the sensor has good sensitivity, with the limit of detection of 1.26 µmol L-1.
ABSTRACT
Heart fatty acid-binding protein (H-FABP) belongs to a family of intracellular fatty acid-binding proteins that are involved in the transport of long-chain fatty acids. Previous studies have indicated that H-FABP is significantly associated with intramuscular fat (IMF) content in pig. In this study, we compared the mRNA and protein expression of H-FABP between Tibetan pig (with high IMF) and Large White pig (with low IMF). The expression of H-FABP at both mRNA and protein levels in the tissues of backfat, longissimus dorsi muscle and liver was found to be significantly higher in TP than in LW. Single-nucleotide polymorphisms (SNPs) in a 2â¯kb region upstream of the start codon of the gene were screened using Sanger sequencing. We accordingly identified three SNPs (C-1375G, C-314T and T-158G) between the TP and LW populations and genotyped these based on PCR-restriction fragment length polymorphisms (PCF-RFLPs) analysis. The results showed that the C-1375G site might regulate H-FABP gene expression and thus be associated with fat deposition in pigs. Our study provides important data for further investigating the regulatory mechanism of H-FABP for fat deposition in pigs.
