Risultati

Pubblicazioni

Esplorate le intuizioni all’avanguardia: immergetevi nelle pubblicazioni scientifiche del progetto europeo Prometeus, dove l’innovazione incontra l’eccellenza per far progredire la conoscenza e plasmare il futuro della scienza.

Martelli, F., Pifferi, A., Farina, A., Amendola, C., Maffeis, G., Tommasi, F., Cavalieri, S., Spinelli, L., Torricelli, A. (2024). Statistics of maximum photon penetration depth in a two-layer diffusive medium. Biomedical Optics Express 15(2), 1163-1180
Amendola, C., Maffeis, G., Farina, F., Spinelli, L., Torricelli, A., Pifferi, A., Sassaroli, A., Fanelli, D., Tommasi, F., Martelli, F. (2024) Application limits of the scaling relations for Monte Carlo simulations in diffuse optics. Part 1: theory. Optics Express 32(1), 125-150
Amendola, C., Maffeis, G., Farina, F., Spinelli, L., Torricelli, A., Pifferi, A., Sassaroli, A., Fanelli, D., Tommasi, F., Martelli, F. (2024) Application limits of the scaling relations for Monte Carlo simulations in diffuse optics. Part 2: Results. Optics Express 15, 26667-26689
Amendola, C., De Carli, A., Boggini, T., Contini, D., Passera, S., Pesenti, N., … & Fumagalli, M. (2024). Effects of red blood cell transfusion on cerebral hemodynamics of preterm neonates. Neurophotonics, 11(4), 045014-045014
Pandayil, J. T., Boetti, N. G., Janner, D., Durduran, T., & Cortese, L. (2024). Proof of concept validation of bioresorbable optical fibers for diffuse correlation spectroscopy. Biomedical Optics Express, 15(11), 6384-6398
Lacerenza, M., Amendola, C., Bargigia, I., Bossi, A., Buttafava, M., Calcaterra, V., … & Torricelli, A. (2025). Challenging the skin pigmentation bias in tissue oximetry via time-domain near-infrared spectroscopy. Biomedical Optics Express, 16(2), 690-708.
Bertachi, A., Marchiori, H., Dalla Man, C., & Vehi, J. (2025). Managing Blood Glucose in Premature Neonates via Parenteral Nutrition: In-silico Evaluation. IFAC-PapersOnLine, 59(2), 1-6
Marchiori, H., Bonet, J., Galderisi, A., & Dalla Man, C. (2025). The neonate glucose simulator: A new tool for testing a nutritional clinical advisor to regulate glycemia in preterm infants admitted to the neonatal intensive care unit. IFAC-PapersOnLine, 59(2), 161-166

Risultati

Improved model for light propagation in heterogeneous diffusive media (POLIMI)
Updated SCOS instrument simulator for premature brain (ICFO)
Novel SCOS OEM MODULE design (ICFO)
Preclinical Proof of concept demonstrating for the first time the safe and effective skin introduction of silicon microprobes (QuLab Medical)
Proof of concept of the device for the real time monitoring and the cloud (prototype of PEU and PCS) (DAVE)
Integrated TD NIRS and SCOS prototype (Prototype of neopticap) (POLIMI)
Clinical proof of concept that has been reached demonstrates for the first time lactet continuous sensing in humans (QLAB)
Preclinical proof of concept for BHB that has been reached demonstrates for the first time sensing of BHB in pigs (QLAB)
Preclinical model (early wearing and hypoglycemic clamp) Improved model to study the consequence of early weaning/prematurity (UGA)
Final prototype of OptiCap interface (UCL)
First version of the neonate simulator. When finalized, the simulator will be the first neonate simulator and could be used to safely develop and test control algorithm to optimally feed this fragile population (UNIPD)

Standard

Revision of an existing standard: Medical electrical equipment — Part 2-71: Particular requirements for the basic safety and essential performance of functional near-infrared spectroscopy (functional NIRS) equipment (POLIMI)
Revision of an existing standard: Medical electrical equipment — Part 2-85: Particular requirements for the basic safety and essential performance of cerebral tissue oximeter equipment (POLIMI)
Revision of an existing standard: Example of implementation of the fNIRS standard phantom described in IEC 80601-2-71(PIONIRS)
Elaboration of a new standard: Laser speckle based methods do not have standards for testing and validation. ICFO has contributed to these standards (ICFO)