Applications of nanosorbents in dispersive solid phase extraction/microextraction approaches for monitoring of synthetic dyes in various types of samples: A review


Khan W. A., Varanusupakul P., Haq H. U., Arain M. B., Boczkaj G.

Microchemical Journal, vol.208, 2025 (SCI-Expanded) identifier identifier

  • Publication Type: Article / Review
  • Volume: 208
  • Publication Date: 2025
  • Doi Number: 10.1016/j.microc.2024.112419
  • Journal Name: Microchemical Journal
  • Journal Indexes: Science Citation Index Expanded (SCI-EXPANDED), Scopus, Academic Search Premier, BIOSIS, CAB Abstracts, Chemical Abstracts Core, Chimica, Food Science & Technology Abstracts, Index Islamicus, Veterinary Science Database
  • Keywords: Sample preparation, Synthetic dyes, Nanomaterials, Sorbent-based dispersive approaches, Sample analysis, Instrumental method
  • Erciyes University Affiliated: Yes

Abstract

Nanosorbents are frequently used in analytical chemistry for their various applications, including extraction and microextraction of synthetic dyes. Synthetic dyes pose a threat to living organisms, particularly humans, due to their worldwide use in a variety of industries. The removal and quantification of synthetic dyes from various matrices is becoming increasingly important. The use of nanosorbents in dispersive solid phase extraction/microextraction (DSPE/DSPME) based approaches are considered the most sensitive and effective techniques for the preconcentration of synthetic dyes due to its high sample clean-up capability, low usage of solvents, high enrichment (preconcentration) factors assuring low detection limits (LOD) of the overall analytical procedures. This review describes widely used nanosorbents, their key properties, and sorption capability, as well as progress and challenges in popular DSPE/DSPME methods and their types, including magnetic solid phase extraction/microextraction (MSPE/MSPME), dispersive micro-solid phase extraction (D-µ-SPE), and ultrasound-assisted dispersive solid phase extraction/microextraction (UA-DSPE/UA-DSPME) for extraction and quantification of dyes. Nanomaterials synthesis methods are typically divided into bottom-up and top-down methods. Bottom-up techniques include hydrothermal, sol–gel, laser pyrolysis, sonochemical, chemical reduction, inert gas condensation (IGC), co-precipitation, and chemical vapor deposition (CVD). Hydrothermal and CVD are the most commonly used. These methods have several advantages, including low cost, the ability to synthesize with a more controlled design, and the release of low waste. However, suffers from ensuring reproducibility and large-scale production. Top-down techniques involve reducing the size of the bulk material to create nanomaterials. The top-down approaches include electrospinning, laser ablation, etching, mechanical milling, thermal decomposition, and sputtering. Top-down techniques yield high-quality nanostructures with precise shapes. However, costly setup and inefficiency in the case of soft materials are considered the major limitations of these approaches. The analytical instrumental technique is used to perform the final quantitative analysis step in these microextraction-based methods. The most common analytical instruments used with these sorbent-based microextraction techniques are UV–visible spectrophotometers, high performance liquid chromatography (HPLC) with UV or diode array detectors (DADs), and liquid chromatography with mass spectrometers. Among the available methods, dedicated procedures for analysis of popular dyes such as Sudan dyes, sunset yellow, malachite green, methylene blue, crystal violet, tartrazine, and azo dye were developed. These methods provide limit of detection (LOD) values at the ppb range, thus meeting the sensitivity demands for environmental analysis and monitoring.