Oncology, Biophysics, Surfaces, Coatings and Films, Virology
21
Scopus Publications
Scopus Publications
Italian screening protocol and genotypes characterization for HCV elimination (2022–2023) in Ferrara’s province: a real-world study Nicolò Landini, Chiara Chiericati, Michela Boni, Loredana Simone, Massimo Trombini, et al. Scientific Reports, 2025 Hepatitis C virus (HCV) is a worldwide health hazard, and in chronic form (nowadays affecting 50 million people – World Health Organization data) can be lethal. To forestall it, preventive screening is a mandatory approach. Since 2021, Italy conducts a national-wide screening program to eliminate the virus from its population. The team perfected an innovative method throughout the period between 2022 and 2023, to answer that medical necessity and map HCV genotypes. The medical protocol has introduced a dedicated double invitation model for the adherents, with consequential pre-prepared medical consumables allocated. The population was divided in three separate groups: born between 1969 and 1989, addiction services, and prison. Two screening levels were carried out: anti-HCV antibodies (indirect chemiluminescence immunoassay) and quantitative HCV RNA reverse transcription. 51,283 adherents were registered: 447 resulted positive to the first screening round, and 88 to the second (393 and 77 patients respectively from population born between 1969 and 1989). The medical protocol introduced allowed to substantially increase patients and medical staff compliance to HCV screening (adherence: 51.83%, the highest in Italy). HCV genotypes’ distribution was mapped by patients’ age, biological sex and origin over five groups comprehending subtypes 1a(35.06% of the positive population), 1b(27.27%), 2a/2c(10.39%), 3a(22.08%), 4a/4c/4d(5.19%).
Chemoresistive Sensors for Cellular Type Discrimination Based on Their Exhalations Michele Astolfi, Giorgio Rispoli, Mascia Benedusi, Giulia Zonta, Nicolò Landini, et al. Nanomaterials, 2022 The detection of volatile organic compounds (VOCs) exhaled by human body fluids is a recent and promising method to reveal tumor formations. In this feasibility study, a patented device, based on nanostructured chemoresistive gas sensors, was employed to explore the gaseous exhalations of tumoral, immortalized, and healthy cell lines, with the aim of distinguishing their VOC patterns. The analysis of the device output to the cell VOCs, emanated at different incubation times and initial plating concentrations, was performed to evaluate the device suitability to identify the cell types and to monitor their growth. The sensors ST25 (based on tin and titanium oxides), STN (based on tin, titanium, and niobium oxides), and TiTaV (based on titanium, tantalum and vanadium oxides) used here, gave progressively increasing responses upon the cell density increase and incubation time; the sensor W11 (based on tungsten oxide) gave instead unreliable responses to all cell lines. All sensors (except for W11) gave large and consistent responses to RKO and HEK293 cells, while they were less responsive to CHO, A549, and CACO-2 ones. The encouraging results presented here, although preliminary, foresee the development of sensor arrays capable of identifying tumor presence and its type.
Nanostructured SMFEO3 gas sensors: Investigation of the gas sensing performance reproducibility for colorectal cancer screening Andrea Gaiardo, Giulia Zonta, Sandro Gherardi, Cesare Malagù, Barbara Fabbri, et al. Sensors Switzerland, 2020 Among the various chemoresistive gas sensing properties studied so far, the sensing response reproducibility, i.e., the capability to reproduce a device with the same sensing performance, has been poorly investigated. However, the reproducibility of the gas sensing performance is of fundamental importance for the employment of these devices in on-field applications, and to demonstrate the reliability of the process development. This sensor property became crucial for the preparation of medical diagnostic tools, in which the use of specific chemoresistive gas sensors along with a dedicated algorithm can be used for screening diseases. In this work, the reproducibility of SmFeO3 perovskite-based gas sensors has been investigated. A set of four SmFeO3 devices, obtained from the same screen-printing deposition, have been tested in laboratory with both controlled concentrations of CO and biological fecal samples. The fecal samples tested were employed in the clinical validation protocol of a prototype for non-invasive colorectal cancer prescreening. Sensors showed a high reproducibility degree, with an error lower than 2% of the response value for the test with CO and lower than 6% for fecal samples. Finally, the reproducibility of the SmFeO3 sensor response and recovery times for fecal samples was also evaluated.
Colorectal cancer study with nanostructured sensors: Tumor marker screening of patient biopsies Michele Astolfi, Giorgio Rispoli, Gabriele Anania, Veronica Nevoso, Elena Artioli, et al. Nanomaterials, 2020 Despite the great progress in screening techniques and medical treatments, colorectal cancer remains one of the most widespread cancers in both sexes, with a high death rate. In this work, the volatile compounds released from human colon cancer tissues were detected by a set of four different chemoresistive sensors, made with a nanostructured powder of metal-oxide materials, inserted into an innovative patented device. The sensor responses to the exhalation of a primary cancer sample and of a healthy sample (both of the same weight, collected during colorectal surgery from the intestine of the same patient) were statistically analyzed. The sensors gave reversible, reproducible, and fast responses for at least one year of continuous use, making them quite superior in respect to the existing diagnostic methods. Preliminary results obtained using principal component analysis of the sensor responses to samples removed from 13 patients indicate that the nanostructured sensors employed in this study were able to distinguish between healthy and tumor tissue samples with coherent responses (the discrimination power of the most sensitive sensor was about 17%), highlighting a strong potential for clinical practice.
Nanostructured chemoresistive sensors for oncological screening and tumor markers tracking: Single sensor approach applications on human blood and cell samples Nicolò Landini, Gabriele Anania, Michele Astolfi, Barbara Fabbri, Vincenzo Guidi, et al. Sensors Switzerland, 2020 Preventive screening does not only allow to preemptively intervene on pathologies before they can harm the host; but also to reduce the costs of the intervention itself; boosting the efficiency of the NHS (National Health System) by saving resources for other purposes. To improve technology advancements in this field; user-friendly yet low-cost devices are required; and various applications for gas sensors have been tested and proved reliable in past studies. In this work; cell cultures and blood samples have been studied; using nanostructured chemoresistive sensors; to both verify if this technology can reliably detect tumor markers; and if correlations between responses from tumor line metabolites and the screening outcomes on human specimens could be observed. The results showed how sensors responded differently to the emanations from healthy and mutant (for cells) or tumor affected (for blood) samples, and how those results were consistent between them, since the tumoral specimens had higher responses compared to the ones of their healthy counterparts. Even though the patterns in the responses require a bigger population to be defined properly; it appeared that the different macro-groups between the same kind of samples are distinguishable from some of the sensors chosen in the study; giving promising outcomes for further research.
