Development of wearable electrochemical sensors for the determination of biological analytes

Wearable biosensors are attracting interest due to their potential to provide continuous, real-time physiological information via dynamic, non-invasive measurements of biochemical markers in biofluids, such as interstitial fluid (ISF). One notable example of their applications is for glycemic monitoring in diabetic patients, which is typically carried out either by direct measurement of blood glucose via finger pricking or by wearable sensors that can continuously monitor glucose in ISF by sampling it from below the skin with a microneedle. In this context, the development of a new and minimally invasive multisensing tattoo-based platform for the monitoring of glucose and other analytes in ISF extracted through reverse iontophoresis in proposed by the GLUCOMFORT project. This elaborate describes the in-vitro development of flexible electrochemical sensors based on inkjet-printed PEDOT:PSS and metal inks that are capable of determining glucose and chloride at biologically relevant concentrations, making them good candidates for application in the GLUCOMFORT platform. In order to make PEDOT:PSS sensitive to glucose at micromolar concentrations, a biocompatible functionalization based on immobilized glucose oxidase and electrodeposited platinum was developed. This functionalization was successfully applied to bulk and flexible amperometric devices, the design of which was also optimized. Using the same strategy, flexible organic electrochemical transistors (OECTs) for glucose sensing were also made and successfully tested. For the sensing of chloride ions, an organic charge-modulated field-effect transistor (OCMFET) featuring a silver/silver chloride modified floating gate electrode was developed and tested.

Studio sulla distribuzione dell'inquinamento da idrocarburi clorurati nelle falde della Provincia di Ferrara.

La Provincia di Ferrara ha avuto (ed ha tuttora) sul suo territorio, insediamenti produttivi di varia natura, che nel tempo hanno fatto uso di idrocarburi alifatici clorurati, per scopi diversi: solventi, sgrassanti, refrigeranti, supporti chimici e farmaceutici, ecc. Soprattutto nei decenni passati, a causa di normative poco restringenti sull’uso e sullo smaltimento di questi composti, si sono verificate le condizioni per provocare l’inquinamento delle falde del territorio provinciale. Nel corso degli anni, si sono svolti studi di diverso carattere, finalizzati ad individuare e caratterizzare siti (o raggruppamenti di siti) contaminati da idrocarburi clorurati. In questo lavoro si è allargata l’attenzione a tutti i siti presenti nel territorio definito dai limiti amministrativi della Provincia di Ferrara, che, nell‘arco temporale 2000 – 2015, hanno evidenziato contaminazioni da CAHs nell’acquifero superficiale A0 e/o nell’acquifero confinato A1. Si sono create, quindi, carte di distribuzione dei siti inquinati su scala provinciale, analizzandone principalmente caratteristiche idrogeologiche e variazioni di distribuzione chimica nello spazio e nel tempo, in relazione agli studi di caratterizzazione ed a eventuali messe in sicurezza e/o bonifiche. I dati necessari sono stati reperiti dagli atti amministrativi e dai relativi documenti tecnici, messi a disposizione dalla Provincia di Ferrara. L’attenzione è ricaduta in particolare sul cloruro di vinile (Vinyl Chloride, VC) ritrovato in alte concentrazioni e in un alto numero di siti. Il suo non utilizzo diretto nei processi produttivi in esame, ne esclude la presenza in qualità di contaminante primario, classificandolo come prodotto della degradazione di altri idrocarburi clorurati più complessi, in larga parte etileni clorurati. Si è inoltre appurato, come la presenza di VC non sia solo attribuibile a siti operanti nel settore metallurgico o chimico, ma riguardi in alcuni casi inquinamenti provocati da commercio o stoccaggio di carburanti, a cui, in passato, furono aggiunti solventi clorurati per migliorarne le caratteristiche chimico-fisiche. Si è concluso infine, come nel territorio della Provincia di Ferrara siano frequenti condizioni particolari, che favoriscono la degradazione di composti organo-clorurati complessi, ed agevolano l’accumulo di cloruro di vinile. Tali caratteristiche, sono state principalmente individuate nella diffusa presenza di livelli fini, anche torbosi, e nella altrettanto diffusa presenza di ambienti riducenti, non solo nel caso dell’acquifero confinato A1 ma anche nel caso dell’acquifero superficiale A0.

Crystallization and morphology of the PLLA phase within random poly (L-lactide-ran-ɛ-caprolactone)

This work has mainly focused on the poly (L-lactide) (PLLA) which is a material for multiple applications with performances comparable to those of petrochemical polymers (PP, PS, PET, etc. ...), readily recyclable and also compostable. However, PLLA has certain shortcomings that limit its applications. It is a brittle, hard polymer with a very low elongation at break, hydrophobic, exhibits low crystallization kinetics and takes a long time to degrade. The properties of PLLA may be modified by copolymerization (random, block, and graft) of L-lactide monomers with other co-monomers. In this thesis it has been studied the crystallization and morphology of random copolymers poly (L-lactide-ran-ε-caprolactone) with different compositions of the two monomers since the physical, mechanical, optical and chemical properties of a material depend on this behavior. Thermal analyses were performed by differential scanning calorimetry (DSC) and thermogravimetry (TGA) to observe behaviors due to the different compositions of the copolymers. The crystallization kinetics and morphology of poly (L-lactide-ran-ε-caprolactone) was investigated by polarized light optical microscopy (PLOM) and differential scanning calorimetry (DSC). Their thermal behavior was observed with crystallization from melt. It was observed that with increasing amounts of PCL in the copolymer, there is a decrease of the thermal degradation. Studies on the crystallization kinetics have shown that small quantities of PCL in the copolymer increase the overall crystallization kinetics and the crystal growth rate which decreases with higher quantities of PCL.

Bioactivity of extracts from extremophile microalgae Coccomyxa sp. on chloride cells in operculum tissue of Fundulus heteroclitus

Microalgae have been studied because of their great potential as a source of new compounds with important value for biotechnology and to understand their strategies of survival in extreme environments. The microalgae Coccomyxa sp., studied in this thesis, is a poly-extremophile witch was isolated from the acid mine drainage of S. Domingos mine. This environment is characterized by low pH (<3) and high concentration of metals, such as copper and iron. The main purpose of the present work was to evaluate the potential bioactivity in an ex-vivo animal model (Fundulus heteroclitus), and expression on selected genes, of cellular extracts obtained from cultures of Coccomyxa sp. at pH 7 without or with exposure to copper (0.6mM Cu²+). The extracts of Coccomyxa sp. cultured at pH 7 exposed to copper show a great potential to be used as epithelial NKCC inhibitors, revealing their potential use as diuretics, but did not show significant effects on gene expression. Coccomyxa sp. could be a good source of cellular extracts with a great potential to be used in pharmaceutical and biotechnology industries.

Inkjet-printed poly(N-isopropylacrylamide)/graphene electrodes for selective electroanalytical sensing

The main research topic of the present master thesis consisted in the modification and electrochemical testing of inkjet printed graphene electrodes with a thin polymeric hydrogel layer made of cross-linked poly(N-isopropylacrylamide) (PNIPAAM) acting as a functional layer to fabricate selective sensors. The first experimental activities dealt with the synthesis of the polymeric hydrogel and the modification of the active surface of graphene sensors through photopolymerization. Simultaneous inkjet printing and photopolymerization of the hydrogel precursor inks onto graphene demonstrated to be the most effective and reproducible technique for the modification of the electrode with PNIPAAM. The electrochemical performance of the modified electrodes was tested through cyclic voltammetry. Voltammograms with standard redox couples with either positive, neutral or negative charges, suggested an electrostatic filtering effect by the hydrogel blocking negatively charged redox species in near neutral pH electrolyte solutions from reaching the electrode surface. PNIPAAM is a known thermo-responsive polymer, but the variation of temperature did not influence the filtering properties of the hydrogels for the redox couples studied. However, a variation of the filter capacity of the material was observed at pH 2 in which the PNIPAAM hydrogel, most likely in protonated form, became impermeable to positively charged redox species and permeable to negatively charged species. Finally, the filtering capacity of the electrodes modified with PNIPAAM was evaluated for the electrochemical determination of analytes in presence of negatively charge potential interferents, such as antioxidants like ascorbic acid. The outcome of the final experiments suggested the possibility to use the inkjet-printed PNIPAAM thin layer for electroanalytical applications as an electrostatic filter against interferents of opposite charges, typically present in complex matrices, such as food and beverages.