Fluorescence Signal Amplification: Red Carbon Dots@SiO2-Induced Ultra-sensitive Immunoassay for Diethyl Phthalate

Surface-modified carbon quantum dot for enhanced fluorescent-sensing of hexagonal valent chromium

As one of the most harmful heavy metal pollutants, hexavalent chromium Cr(VI) is becoming a serious threat to human health. Thus pursuing a remarkably sensitive method to monitor the Cr(VI) concentration in natural conditions is favored for the fast response to prevent harm. In the present work, an ethylenediamine (En) and SiO2-modified wool keratin-based carbon quantum dot (CQD)(En@CQDs@SiO2) fluorescent sensor is prepared, and the En is found to improve the discrimination ability by binding the Cr(VI) with the surface carboxyl groups. Based on these designs, the En@CQDs@SiO2 achieves a significant improvement in the Cr(VI) detection ability, with a detection limit of 6.08 × 10-4 mg/L, which succeeded 6 times over CQDs, and is better than conventional UV-Vis and flame atomic absorption (AAS) techniques. Furthermore, the fluorescent sensor has good relative sensitivity, selectivity, good spectral reproducibility, and excellent structural stability. These properties make the sensor suitable for environmental Cr(VI) detection, which undoubtedly improves the economy and environmental friendliness of the fluorescent sensor.

Quantitative Intracellular Delivery of Anticancer Nanodrugs Via an Immunoassay Employing Pt-SiO2 Janus-Peroxidase Nanozyme

The accurate and efficient quantification of nanodrug dosage is crucial for early anticancer therapy. The enzyme-linked immunosorbent assay (ELISA) has emerged as a robust tool for detecting anticancer nanodrug dosage; however, the development of sensing elements to quantify anticancer nanodrugs still poses a challenge. To overcome this problem, we utilize polysuccinimide-loaded curcumin (CUR @PSIOAm) as a model to employ an ELISA based on peroxidase nanozyme Pt-SiO2 Janus nanoparticles (Pt-SiO2 JNPs) for the indirect quantitative analysis of intracellular anticancer nanodrug dosage. This novel approach employs an immunoassay to indirectly quantify the dosage of anticancer nanodrugs while preserving its structural integrity. The silica components of Pt-SiO2 JNPs adsorb intermediates, while the Pt NP components exhibit high catalytic activity. Pt-SiO2 JNPs are functionalized with anti-PSIOAm antibody (Pt-SiO2 JNPs-Ab) to serve as an immunosensor capable of specific recognition of CUR @PSIOAm. Additionally, we employed cytotoxicity assays and confocal imaging techniques to demonstrate the excellent biocompatibility of CUR @PSIOAm, as well as its specific uptake by cancer cells. According to the experimental results, the limit of detection (LOD) for the immunoassay of Pt-SiO2 JNPs as a marker for detecting CUR @PSIOAm is approximately 4.5-fold lower than that of horseradish peroxidase. Therefore, by optimizing the conditions, we established a direct competitive ELISA using Pt-SiO2 JNPs as colorimetric indicators for the quantitative detection of intracellular CUR @PSIOAm. The LOD for this ELISA was determined to be 0.01 ng/mL, while the loaded CUR amount calculated from the drug loading capacity was found to be 0.22 pg/mL. Furthermore, the recoveries obtained from this established ELISA ranged between 94.0 and 108%, demonstrating excellent accuracy. Consequently, the peroxidase mimic Pt-SiO2 JNPs-based ELISA exhibits significant potential for precise quantification of intracellular anticancer nanodrug dosages.

Carbon dot-based fluorescent probe for early diagnosis of pheochromocytoma through identification of circulating tumor cells

Pheochromocytoma (PCC), as a rare neuroendocrine tumor, is often missed or misdiagnosed because of its atypical clinical manifestations. To realize the early accurate diagnosis of PCC, we have selected circulating tumor cells (CTCs) with more complete biological information as biomarkers and developed a simple and novel fluorescence cytosensor. Octreotide-2,2',2'',2'''- (1,4,7,10 -tetraazacyclododecane-1,4,7,10-tetrayl) tetraacetic acid (DOTA) modified magnetic Fe3O4 and signal amplification CDs@SiO2 nanospheres are prepared to capture and detect PCC-CTCs from peripheral blood via binding to the somatostatin receptor SSTR2 overexpressed on the surface of PCC cells. During the detection process, the target cells were separated and enriched by magnetic capture probes (Fe3O4-DOTA), and then signal probes (CDs@SiO2-DOTA) could also specifically bound to target cells to form the sandwich-like structure for fluorescence signal output. The proposed fluorescence cytosensor has revealed good sensitivity and selectivity for quantitative analysis of PCC-CTCs in the concentration of 5-1000 cells mL-1 with a LOD of 2 cells mL-1. More importantly, designed fluorescence cytosensor has shown good reliability and stability in complex serum samples. This strategy provides a new way for detection of PCC-CTCs.

A review on solution- and vapor-responsive sensors for the detection of phthalates

Phthalic acid esters, largely referred to as phthalates, are today acknowledged as important pollutants used in the manufacture of polyvinyl chloride (PVC)-based plastics, whose use extends to almost every aspect of modern life. The risk of exposure to phthalates is particularly relevant as high concentrations are regularly found in drinking water, food-contact materials and medical devices, motivating an immense body of research devoted to methods for their detection in liquid samples. Conversely, phthalate vapors have only recently been acknowledged as potentially important atmospheric pollutants and as early fire indicators; additionally, deposition of these vapors can pose significant problems to the proper functioning of spacecraft and diverse on-board devices, leading to major space agencies recognizing the need of developing vapor-responsive phthalate sensors. In this manuscript we present a literature survey on solution- and vapor-responsive sensors and analytical assays for the detection of phthalates, providing a detailed analysis of a vast array of analytical data to offer a clear idea on the analytical performance (limits of detection and quantification, linear range) and advantages provided by each class of sensor covered in this review (electrochemical, optical and vapor-responsive) in the context of their potential real-life applications; the manuscript also gives detailed fundamental information on the various physicochemical responses exploited by these sensors and assays that could potentially be harnessed by new researchers entering the field.