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Design and application of structured fluorometric sensor for melamine detection in milk powder
Mahmood Alizadeh Sani, Arezou Khezerlou, Mohammad Rezvani-Ghalhari, Gholamreza Jahed-Khaniki,
Volume 18, Issue 3 (12-2025)
Abstract
Background and Objective: Melamine is a chemical compound commonly used as an adulterant in food products. In this study, a fluorescence-based sensor utilizing an aluminum metal-organic framework (Al−MOF) was developed for the detection of melamine in milk powder.
Materials and Methods: In this study, Al-MOF was employed as a sensing material due to its high fluorescence properties and strong ability to adsorb melamine. Using fluorescence techniques, the sensitivity and selectivity of the sensor towards melamine were evaluated over a concentration range of 0 to 400 nanomolar (nM).
Results: The melamine concentration was determined based on the reduction in the fluorescence intensity of the Al-MOF. The effects of different parameters such as pH, reaction time, and concentration, on the performance of the designed sensor were evaluated. Under optimized conditions (pH = 9, reaction time < 1 min, and Al–MOF concentration of 30 mg/L), a good linear relationship (R2 = 0.99) was observed between fluorescence intensity and melamine concentration in the range of 0–400 nM, with a detection limit of 38.5 ppb. However, the limit of detection (LOD) for HPLC method was approximately 90 ppb, indicating that the designed sensor has higher sensitivity (about 2.3 times). The sensor also exhibited good selectivity for melamine. The recovery percentage and relative standard deviation (RSD) were found to be 97-103% and 1.2-2.8%, respectively.
Conclusion: This sensor can serve as an effective tool for quality control in dairy products due to its simplicity and rapid detection capabilities.
 

Benzene removal from air using Bi2O3–TiO2 photocatalyst coated on glass foam under ultraviolet light irradiation
Ramazanali Dianati Tilaki, Roghayeh Kaseb, Esmaeil Babanejad Arimi, Mohammad Dianati,
Volume 18, Issue 3 (12-2025)
Abstract
Background and Objective: Benzene is a carcinogenic volatile organic compound commonly found in polluted air. This study aimed to remove benzene from air using a TiO₂–Bi2O₃ composite photocatalyst immobilized on glass foam under ultraviolet (UV) light irradiation.
Materials and Methods: Glass foam coated with the TiO₂– Bi2O₃composite was placed in a quartz reactor, which was connected to an air pump inside a sealed glass chamber. A UV lamp (254 nm) was installed next to the reactor. Known volumes (µL) of benzene were injected into the chamber through a septum. When the pump was activated, benzene-contaminated air passed through the photoreactor. Benzene concentration was measured by collecting air samples from the chamber and analyzing them using a GC-FID device.
Results: XRD spectra and SEM images confirmed the presence of TiO₂ and Bi2O₃, while BET analysis verified the mesoporous structure of the composite photocatalyst. The surface adsorption of benzene by the composite was 15% and followed the Langmuir model. The process kinetics were first-order, and the removal efficiency decreased with increasing benzene concentration. At a benzene concentration of 39 ppm, the removal efficiency after 75 minutes of TiO₂ and UV irradiation was 75%, whereas for TiO₂– Bi2O₃ under similar conditions, the efficiency increased to approximately 90%.
Conclusion: Using a TiO₂– Bi2O₃ composite photocatalyst under UV-A irradiation improved benzene removal efficiency by about 15% compared with TiO₂alone.
 

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