One of the main challenges to be faced in deep space missions is to protect the health and ensure the maximum efficiency of the crew by preparing methods of prevention and in situ diagnosis. Indeed, the hostile environment causes important health problems, ranging from muscle atrophy, osteopenia, and immunological and metabolic alterations due to microgravity, to an increased risk of cancer caused by exposure to radiation. It is, therefore, necessary to provide new methods for the real-time measurement of biomarkers suitable for deepening our knowledge of the effects of space flight on the balance of the immune system and for allowing the monitoring of the astronaut’s health during long-term missions. APHRODITE will enable human space exploration because it fills this void that affects both missions in LEO and future missions to the Moon and Mars. Its scientific objectives are the design, production, testing, and in-orbit demonstration of a compact, reusable, and reconfigurable system for performing the real-time analysis of oral fluid samples in manned space missions. In the frame of this project, a crew member onboard the ISS will employ APHRODITE to measure the selected target analytes, cortisol, and dehydroepiandrosterone sulfate (DHEA-S), in oral fluid, in four (plus one additional desired session) separate experiment sessions. The paper addresses the design of the main subsystems of the analytical device and the preliminary results obtained during the first implementations of the device subsystems and testing measurements on Earth. In particular, the system design and the experiment data output of the lab-on-chip photosensors and of the front-end readout electronics are reported in detail along with preliminary chemical tests for the duplex competitive CL-immunoassay for the simultaneous detection of cortisol and DHEA-S. Different applications also on Earth are envisaged for the APHRODITE device, as it will be suitable for point-of-care testing applications (e.g., emergency medicine, bioterrorism, diagnostics in developing countries, etc.).

APHRODITE. A compact lab-on-chip biosensor for the real-time analysis of salivary biomarkers in space missions / Nardi, Lorenzo; Davis, Nithin Maipan; Sansolini, Serena; Baratto de Albuquerque, Thiago; Laarraj, Mohcine; Caputo, Domenico; de Cesare, Giampiero; Shariati Pour, Seyedeh Rojin; Zangheri, Martina; Calabria, Donato; Guardigli, Massimo; Balsamo, Michele; Carrubba, Elisa; Carubia, Fabrizio; Ceccarelli, Marco; Ghiozzi, Michele; Popova, Liyana; Tenaglia, Andrea; Crisconio, Marino; Donati, Alessandro; Nascetti, Augusto; Mirasoli, Mara. - In: BIOSENSORS. - ISSN 2079-6374. - 14:2(2024), pp. 1-19. [10.3390/bios14020072]

APHRODITE. A compact lab-on-chip biosensor for the real-time analysis of salivary biomarkers in space missions

Nardi, Lorenzo
;
Davis, Nithin Maipan;Sansolini, Serena;Baratto de Albuquerque, Thiago;Caputo, Domenico;de Cesare, Giampiero;Donati, Alessandro;Nascetti, Augusto;
2024

Abstract

One of the main challenges to be faced in deep space missions is to protect the health and ensure the maximum efficiency of the crew by preparing methods of prevention and in situ diagnosis. Indeed, the hostile environment causes important health problems, ranging from muscle atrophy, osteopenia, and immunological and metabolic alterations due to microgravity, to an increased risk of cancer caused by exposure to radiation. It is, therefore, necessary to provide new methods for the real-time measurement of biomarkers suitable for deepening our knowledge of the effects of space flight on the balance of the immune system and for allowing the monitoring of the astronaut’s health during long-term missions. APHRODITE will enable human space exploration because it fills this void that affects both missions in LEO and future missions to the Moon and Mars. Its scientific objectives are the design, production, testing, and in-orbit demonstration of a compact, reusable, and reconfigurable system for performing the real-time analysis of oral fluid samples in manned space missions. In the frame of this project, a crew member onboard the ISS will employ APHRODITE to measure the selected target analytes, cortisol, and dehydroepiandrosterone sulfate (DHEA-S), in oral fluid, in four (plus one additional desired session) separate experiment sessions. The paper addresses the design of the main subsystems of the analytical device and the preliminary results obtained during the first implementations of the device subsystems and testing measurements on Earth. In particular, the system design and the experiment data output of the lab-on-chip photosensors and of the front-end readout electronics are reported in detail along with preliminary chemical tests for the duplex competitive CL-immunoassay for the simultaneous detection of cortisol and DHEA-S. Different applications also on Earth are envisaged for the APHRODITE device, as it will be suitable for point-of-care testing applications (e.g., emergency medicine, bioterrorism, diagnostics in developing countries, etc.).
2024
lab-on-chip; chemiluminescence; hydrogenated amorphous silicon photosensors; biosensor; international space station; immunoassay
01 Pubblicazione su rivista::01a Articolo in rivista
APHRODITE. A compact lab-on-chip biosensor for the real-time analysis of salivary biomarkers in space missions / Nardi, Lorenzo; Davis, Nithin Maipan; Sansolini, Serena; Baratto de Albuquerque, Thiago; Laarraj, Mohcine; Caputo, Domenico; de Cesare, Giampiero; Shariati Pour, Seyedeh Rojin; Zangheri, Martina; Calabria, Donato; Guardigli, Massimo; Balsamo, Michele; Carrubba, Elisa; Carubia, Fabrizio; Ceccarelli, Marco; Ghiozzi, Michele; Popova, Liyana; Tenaglia, Andrea; Crisconio, Marino; Donati, Alessandro; Nascetti, Augusto; Mirasoli, Mara. - In: BIOSENSORS. - ISSN 2079-6374. - 14:2(2024), pp. 1-19. [10.3390/bios14020072]
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11573/1700871
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