Rapid Sensing of Specific Drugs at Sub‐Ppb Levels by Using a Hybrid Organic–Inorganic Photoluminescent Soft Material

Afzal

2022

Helvetica Chimica Acta

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Photoluminescent supramolecular systems such as hydrogels and metal‐organic frameworks (MOFs) can be useful for applications in many areas. In aqueous media, lanthanides exhibit luminescence by sensitization through covalently linked chromophores (antenna effect), making them valuable for sensing and imaging applications. Fluorescent sensing by sensitized lanthanide emission in gels and MOFs provides a simple and rapid detection of analytes with high sensitivity and selectivity. This review presents the gradual evolution and the intriguing conceptualization of sensitized luminescence of lanthanides spanning the sensing of biomolecules, drugs, small organic molecules and enzymes employing hydrogels or MOFs as the sensing platform.

Section: Photoluminescent Hydrogels As Sensorsmentioning

confidence: 99%

Sensitized Lanthanide Photoluminescence Based Sensors–a Review

Afzal

2022

Helvetica Chimica Acta

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“…In the recent years, we have extensively worked on photoluminescent lanthanide cholate hydrogels [40,41] . We have shown the potential applications of these hydrogels for enzyme assays, [42,43] generating color‐tunable photoluminescent gels and xerogels including white light emitting gels, [40] for the synthesis of LnF 3 nanoparticles [44] and sensing naphthalene based drugs [45] . Recently, we also demonstrated a low‐cost, paper‐based approach for assaying various biologically important hydrolases [43,46] …”

Section: Figurementioning

confidence: 99%

“…[40,41] We have shown the potential applications of these hydrogels for enzyme assays, [42,43] generating color-tunable photoluminescent gels and xerogels including white light emitting gels, [40] for the synthesis of LnF 3 nanoparticles [44] and sensing naphthalene based drugs. [45] Recently, we also demonstrated a low-cost, paper-based approach for assaying various biologically important hydrolases. [43,46] In this work, we observed that a Tb cholate (TbCh) gel doped with GA or its derivatives EGCG or ECG showed green luminescence under 365 nm UV lamp (Figure 1a).…”

mentioning

confidence: 99%

An Inexpensive Paper‐Based Photoluminescent Sensor for Gallate Derived Green Tea Polyphenols

Gorai

Sakthivel

Chemistry An Asian Journal

2020

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This work describes a terbium luminescencebased protocol to selectively detect gallate-derived green tea polyphenols on a supramolecular gel immobilised paper platform for the first time. This user-friendly, inexpensive (E 0.0015) approach requires very low sample volumes for the analysis. The developed strategy enables simultaneous detection of gallate polyphenols in multiple tea samples with the potential for practical applications. Antioxidants play important roles by reducing oxidative stress and improving metabolic functions of living beings. [1] Gallic acid (GA) is one such important naturally occurring antioxidant present in several foods [2] and has been reported to have health benefits with anti-inflammatory, anti-cancer, antimicrobial, antiradical, anti-aging properties and also provides protection from cardiovascular and neurodegenerative diseases. [3-5] In this respect, green tea, a rich source of antioxidants is becoming one of the most popular beverages in the world market with increased awareness about its multiple health benefits. [6] Research has revealed that it contains a number of polyphenols that are powerful antioxidants and are responsible for the beneficial effects attributed to green tea. These polyphenols constitute up to 30% of the total dry weight of green tea. [7] Out of the eight different polyphenols present in green tea, four are gallate polyphenols: catechin gallate (CG), epicatechin gallate (ECG), gallocatechin gallate (GCG) and epigallocatechin gallate (EGCG). The non-gallate polyphenols are catechin (C), epicatechin (EC), gallocatechin (GC) and epigallocatechin (EGC) (Figure S1). [8] Generally, the gallate polyphenols are known to have more beneficial effects than other polyphenols as the galloyl moiety is known to play important roles in the health benefits credited to green tea. [9,10] EGCG, a gallate ester, is the most abundant and potent polyphenol present in green tea, [a

“…[32] Over a century ago, Schryver reported the first metal cholate hydrogel, viz, calcium cholate (CaCh) gel, [33] but further exploration has been done only from 2009, and now several other metal cholate gels and their applications have been reported. [34][35][36][37][38][39][40][41][42] While a number of metal ions form gels with cholate, we chose calcium and europium cholates (CaCh & EuCh) for detailed studies. CaCh was selected as it showed a clear transition from a transparent sol to a gel ( Figure 1a) slowly (~3 h/25°C), giving sufficient time for kinetic measurements.…”

Section: Introductionmentioning

confidence: 99%

“…Over a century ago, Schryver reported the first metal cholate hydrogel, viz, calcium cholate (CaCh) gel, but further exploration has been done only from 2009, and now several other metal cholate gels and their applications have been reported . While a number of metal ions form gels with cholate, we chose calcium and europium cholates (CaCh & EuCh) for detailed studies.…”

Section: Introductionmentioning

confidence: 99%

Supramolecular Gelation of Europium and Calcium Cholates through the Nucleation‐Elongation Growth Mechanism

Laishram

2019

ChemPlusChem

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A detailed understanding of gelation mechanism can enable the properties of gels to be tuned for various applications, and may possibly help in understanding the aggregation of different biomolecules. We report a detailed study of the morphological and physio‐chemical changes, dynamics (of a probe), and kinetics during the gelation of europium and calcium cholate hydrogels, leading to the development of a growth model. AFM images showed the transition of aggregated particles (100–150 nm) in the sol phase growing to a fibrous network in the gel through the entanglement of fibres, and not by dendritic growth (height analysis). The dynamic changes during this phase transformation were studied using a fluorescence probe (change in intensity and lifetime). We have been able to delineate the growth mechanism by using a combination of Eu(III) luminescence and a polarity sensitive fluorescence probe. The growth was found to follow the nucleation–elongation model, and these two phases responded in distinctly different fashions in rheological and luminescence measurements.