The use of pesticides has been continuously increasing worldwide since their introduction in the global market, with the aim of fulfilling the needs of the growing population. While their monitoring in the environment has been thoroughly addressed, the bioaccumulation of pesticides in the human body is an ongoing challenge, due to the complexity of the biological matrices in which pesticides tend to accumulate (e.g., urine, blood, sweat, and more). Most of the developed strategies rely on time-consuming sample preparation or expensive and polluting reagents for the construction of the sensing platform. In the view of developing a green alternative device to handle pesticide analysis in biofluids, we designed an enzymatic paper-based electrochemical sensor for glyphosate (GLY) detection in human urine. The pesticide quantification is obtained by measuring the grade of enzyme inhibition by both GLY and uric acid (UA), the latter being one of the principal components of human urine. GLY detection is carried out by measuring the initial and residual enzymatic activity in chronoamperometric tests, taking into consideration the contribution of UA to the inhibition. In addition to the specific application here described, this work aims at providing an emblematic example of how to design green sensing solutions for addressing analytical challenges related to health control, delivering low-impact methods based on sustainable materials (e.g., paper), non-toxic reagents, and minimal waste production while ensuring competitive analytical performances.

Heavy metals ions (HMI) are micropollutants that represent a growing environmental problem, as they have influenced various components of the environment, such as terrestrial and aquatic biota. Among HMI, lead and cadmium are highly toxic, and even small doses can lead to harmful effects on human health. Thus, rapid methods to detect these metals in multi-matrices are urgently required. Here, an electrochemical sensor screen-printed onto a flexible substrate has been coupled with a paper-based platform for the determination of HMI in clinical, environmental and food matrices have been developed. The bismuth film-based flexible device has been optimized and it has been able to detect cadmium and lead, respectively, down to the detection limit of 1.3 and 2 ppb. The use of chromatographic paper has allowed to improve the sensitivity towards the detection of HMI, because of the porosity that allowed to pre-concentrate species. The combination of this platform with a paper-based one has allowed to enhance the sensitivity of the whole device, with a detection limit of 0.3 and 0.5 ppb, respectively, to cadmium and lead, and offers the possibility to tune the sensitivity according to needs, e.g., improving the number of pre-concentration steps. The electrochemical sensor was evaluated in drinking water, mussel and blood serum, demonstrating how these hybrid polyester-paper electrochemical strips can significantly lower the time and costs for on-site measurements, through analytical methods of simple use. The accuracy has been evaluated by comparison with ICP-MS measurements, giving satisfactory results.

DOI 10.1149/1945-7111/ac5c98

Three-dimensional (3D) printing has gained significant attention from industry and research laboratories, as it empowers the end user with the freedom to create in-house and on-demand specialized electrochemical systems adapted to immediate bioanalytical needs. Fused deposition modeling (FDM) is based on the CAD design of the sensor and its printing from thermoplastic filaments. FDM presents advantageous features such as low-cost portable printers, ease of operation, flexibility in the design, design transferability, and thus, it can complement and in some cases replace, existing fabrication technologies [1,2,3].

This presentation will discuss our recent developments of 3D-printed integrated chips and their applications to electrochemical biosensing [4,5,6]. The devices are printed from specific filaments (conductive and non-conductive) at different sizes and shapes, by a dual extruder 3D printer, in order to fit to the demands of various applications. More specifically, integrated all-3D-printed electrochemical microtitration wells (e-wells) for the in-situ and micro-volume quantum dot based bioassays will be described. Besides, a 3D printed 4-electrode biochip for the enzymatic simultaneous determination of two biomarkers and a 3D printed wearable glucose monitoring device in the form of an electrochemical ring (e-ring) will be presented.

References

1. A. Abdalla and B. A. Patel, Curr. Opin. Electrochem, 20 (2020) 78–81.
2. E. J. Carrasco-Correa, E. F. Simó-Alfonso, J. M. Herrero-Martínez, M. Miró, TrAC - Trends Anal. Chem., 136 (2021) 116177.
3. V. Katseli, A. Economou, C. Kokkinos, Electrochem. Commun. 103 (2019) 100–103.
4. V. Katseli, M. Angelopoulou, C. Kokkinos, Adv. Funct. Mater., (2021) 2102459.
5. V. Katseli, A. Economou, C. Kokkinos, Anal. Chem. 93 (2021) 3331−3336.
6. E. Koukouviti, C. Kokkinos, Anal. Chim. Acta 1186 (2021) 339114

Ochratoxin A (OTA) is a mycotoxin produced by several fungal species and various studies have shown that OTA can cause several adverse health effects to animals and humans through its consumption in contaminated plant foods such as coffee, beer, wine, corn, wheat, oats and vegetables [1]. OTA has been shown to be nephrotoxic, teratogenic, immunotoxic, and carcinogenic in human health. In particular, the International Agency for Research on Cancer has classified OTA as a group 2B carcinogen [2]. Due to the toxicity of OTA , the European Union has set maximum limits (MLs) for OTA in foods in the range of 0.5–10 μg kg⁻¹ [2]. Therefore, the development of a cheap, sensitive and rapid method for OTA detection in plant-based foods is essential.

The detection of OTA in food is mostly based on chromatographic techniques, which although powerful , require expensive equipment, trained personel and complex sample preparation [1,2]. Enzyme-linked immunosorbent assay s(ELISA) and immunochromatographic assays are portable, convenient and simple but require expensive and unstable antibodies and normally [3,4]. On the contrary aptamer-based biosensors employ relative inexpensive and stable single stranded oligonucleotides as biorecognition elements, which makes them ideal for rapid on-site detection of OTA [2,5], especially when combined with smartphone-based detection [6].

In this work, we describe a simple, portable and cost-efficient lateral flow biosensor for OTA. The biosensor utilizes an OTA-specific aptamer for biorecognition and is based on a lateral flow assay using a device consisting of a sample pad, a conjugate pad, a test and a control zone, as well as an absorbent pad. The conjugate PAD is loaded with OTA aptamer-AuNPs congugates while the test and control zones are loaded with a specific and a universal probe, respectively. The principle of the assay is that the OTA present in the sample combines with the OTA aptamer-AuNPs congugates and prevents the interaction between the specific probe in the test line and the OTA aptamer-AuNPs congugates; therefore, the intensity of the test line decreases as the concentration of OTA in the sample increases. Quantification of OTA is performed by reflectance calorimetry using a smartphone and image analysis. All the parameters of the assay were investigated in detail and the analytical features were established.

References

[1] Atumo S (2020) A Review of Ochratoxin A Occurrence, Condition for the Formation and Analytical Methods. Int J Agric Sc Food Technol 6(2): 180-185. DOI: 10.17352/2455-815X.000071

[2] Chen, X., Gao, D., Sun, F. et al. Nanomaterial-based aptamer biosensors for ochratoxin A detection: a review. Anal Bioanal Chem 414, 2953–2969 (2022). https://doi.org/10.1007/s00216-022-03960-5

[3] Meulenberg EP. Immunochemical methods for ochratoxin A detection: a review. Toxins (Basel). 2012 Apr;4(4):244-66. doi: 10.3390/toxins4040244. Epub 2012 Apr 13. PMID: 22606375; PMCID: PMC3347002

[4] Bazin I, Nabais E, Lopez-Ferber M. Rapid visual tests: fast and reliable detection of ochratoxin A. Toxins. 2010 Sep;2(9):2230-2241. DOI: 10.3390/toxins2092230

[5] Ha, T.H. Recent Advances for the Detection of Ochratoxin A. Toxins 2015, 7, 5276-5300. https://doi.org/10.3390/toxins7124882

[6] Madrid RE, Ashur Ramallo F, Barraza DE, Chaile RE. Smartphone-Based Biosensor Devices for Healthcare: Technologies, Trends, and Adoption by End-Users. Bioengineering (Basel). 2022 Mar 1;9(3):101. doi: 10.3390/bioengineering9030101

Biocidal disinfectants are used daily throughout the food chain to limit the development of undesirable microorganisms present in the environment or on surfaces in contact with foodstuffs or animal feed.

The presence of residues of these biocidal products is an issue for human health especially if they are not completely removed during rinsing operations.

Today, we aim to develop innovative electrochemical biosensors as powerful analytical methods to detect these residues of biocides.

Enzyme-based biosensors are known to be more sensitive and selective. So far, only one conductometric sensor is known at present for the detection of surfactants [1]. In this light, we suggested applying the acetylcholinesterase-based voltammetric biosensor for inhibitory analysis of quaternary ammonium compounds (QACs).

In this work, we elaborated an enzymatic sensor based on bionanomaterials film consisting of a fil of carboxylic acid functionalized multi-walled carbon nanotubes (c-MWCNT) modified with the acetylcholinesterase enzyme. In addition to their mechanical stability and good electric conductivity, the c-MWCNT in particular display a large number of binding sites available for enzyme immobilization. These cholinesterase-based sensors are very sensitive and allow for reaching low limits of detection.

Cyclic voltammetry was used to characterize the sensing film deposited onto the surface of electrodes such as glassy carbon and gold electrodes (Au250AT, Au250BT).

The acetylcholinesterase sensors that exhibited good repeatability and stability were applied to the detection of residues of QACs in milk samples.

[1] DOI 10.1088/0957-0233/23/6/065801