Publications
Title | Year | Citation |
Remote Electrical Stimulation by Means of Implanted Rectifiers | 2011 | Ivorra, A. (2011). Remote electrical stimulation by means of implanted rectifiers. PLoS One, 6(8), e23456. Link |
Proof of Concept of a Stimulator Based on AC Current Rectification for Neuroprosthetics | 2012 | Becerra Fajardo, L., & Ivorra Cano, A. (2012). Proof of concept of a stimulator based on AC current rectification for neuroprosthetics. Link |
Injectable Rectifiers as Microdevices for Remote Electrical Stimulation: an Alternative to Inductive Coupling |
2013 | Ivorra, A., Sacristán, J., & Baldi, A. (2013). Injectable rectifiers as microdevices for remote electrical stimulation: an alternative to inductive coupling. In World Congress on Medical Physics and Biomedical Engineering May 26-31, 2012, Beijing, China (pp. 1581-1584). Springer, Berlin, Heidelberg. Link |
Wireless Microstimulators Based on Electronic Rectification of Epidermically Applied Currents: Safety and Portability Analysis |
2013 | Ivorra, A., & Becerra-Fajardo, L. (2013). Wireless microstimulators based on electronic rectification of epidermically applied currents: Safety and portability analysis. In 18th IFESS Annual Conference (pp. 213-216). Link |
Towards Addressable Wireless Microstimulators Based on Electronic Rectification of Epidermically Applied Currents |
2014 | Becerra-Fajardo, L., & Ivorra, A. (2014). Towards addressable wireless microstimulators based on electronic rectification of epidermically applied currents. In 2014 36th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (pp. 3973-3976). IEEE. Link |
Charge Counter for Performing Active Charge-balance in Miniaturized Electrical Stimulators |
2014 | Becerra-Fajardo, L., & Ivorra, A. (2015). Charge counter for performing active charge-balance in miniaturized electrical stimulators. In 6th European Conference of the International Federation for Medical and Biological Engineering (pp. 256-259). Springer, Cham. Link |
Flexible Thread-like Electrical Stimulation Implants Based on Rectification of Epidermically Applied Currents Which Perform Charge Balance |
2014 |
Ivorra, A., & Becerra-Fajardo, L. (2014). Flexible Thread-like Electrical Stimulation Implants Based on Rectification of Epidermically Applied Currents Which Perform Charge Balance. In Replace, Repair, Restore, Relieve–Bridging Clinical and Engineering Solutions in Neurorehabilitation (pp. 447-455). Springer, Cham. Link
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Bidirectional Communications in Wireless Microstimulators Based on Electronic Rectification of Epidermically Applied Currents |
2015 | Becerra-Fajardo, L., & Ivorra, A. (2015). Bidirectional communications in wireless microstimulators based on electronic rectification of epidermically applied currents. In 2015 7th International IEEE/EMBS Conference on Neural Engineering (NER) (pp. 545-548). IEEE. Link |
In Vivo Demonstration of Addressable Microstimulators Powered by Rectification of Epidermically Applied Currents for Miniaturized Neuroprostheses |
2015 | Becerra-Fajardo, L., & Ivorra, A. (2015). In vivo demonstration of addressable microstimulators powered by rectification of epidermically applied currents for miniaturized neuroprostheses. PLoS One, 10(7), e0131666. Link |
In vivo demonstration of injectable microstimulators based on charge-balanced rectification of epidermically applied currents |
2015 | Ivorra, A., Becerra-Fajardo, L., & Castellví, Q. (2015). In vivo demonstration of injectable microstimulators based on charge-balanced rectification of epidermically applied currents. Journal of neural engineering, 12(6), 066010. Link |
Demonstration of 2 mm Thick Microcontrolled Injectable Stimulators Based on Rectification of High Frequency Current Bursts |
2016 | Becerra-Fajardo, L., Schmidbauer, M., & Ivorra, A. (2016). Demonstration of 2 mm thick microcontrolled injectable stimulators based on rectification of high frequency current bursts. IEEE Transactions on Neural Systems and Rehabilitation Engineering, 25(8), 1343-1352. Link |
Injectable Stimulators Based on Rectification of High Frequency Current Bursts: Power Efficiency of 2 mm Thick Prototypes | 2016 | Becerra-Fajardo, L., Garcia-Arnau, R., & Ivorra, A. (2017). Injectable stimulators based on rectification of high frequency current bursts: power efficiency of 2 mm thick prototypes. In Converging clinical and engineering research on neurorehabilitation II (pp. 667-671). Springer, Cham. Link |
Powering implants by galvanic coupling: a validated analytical model predicts powers above 1 mW in injectable implants |
2018 | Tudela-Pi, M., Becerra-Fajardo, L., & Ivorra, A. (2019). Powering implants by galvanic coupling: A validated analytical model predicts powers above 1 mW in injectable implants. In World Congress on Medical Physics and Biomedical Engineering 2018 (pp. 23-26). Springer, Singapore. Link |
First Steps Towards an Implantable Electromyography (EMG) Sensor Powered and Controlled by Galvanic Coupling |
2018 | Becerra-Fajardo, L., & Ivorra, A. (2019). First steps towards an implantable electromyography (EMG) sensor powered and controlled by galvanic coupling. In World Congress on Medical Physics and Biomedical Engineering 2018 (pp. 19-22). Springer, Singapore.Link |
Two-Port Networks to Model Galvanic Coupling for Intrabody Communications and Power Transfer to Implants |
2018 | Becerra-Fajardo, L., Tudela-Pi, M., & Ivorra, A. (2018). Two-port networks to model galvanic coupling for intrabody communications and power transfer to implants. In 2018 IEEE Biomedical Circuits and Systems Conference (BioCAS) (pp. 1-4). IEEE. Link |
Power Transfer by Volume Conduction: In Vitro Validated Analytical Models Predict DC Powers above 1 mW in Injectable Implants |
2020 | Tudela-Pi, M., Becerra-Fajardo, L., García-Moreno, A., Minguillon, J., & Ivorra, A. (2020). Power transfer by volume conduction: In vitro validated analytical models predict DC powers above 1 mW in injectable implants. IEEE Access, 8, 37808-37820. Link |
Interleaved intramuscular stimulation with minimally overlapping electrodes evokes smooth and fatigue resistant forces |
2020 | Eladly, A., Del Valle, J., Minguillon, J., Mercadal, B., Becerra-Fajardo, L., Navarro, X., & Ivorra, A. (2020). Interleaved intramuscular stimulation with minimally overlapping electrodes evokes smooth and fatigue resistant forces. Journal of Neural Engineering, 17(4), 046037. Link |
Injectable Sensors Based on Passive Rectification of Volume-Conducted Currents | 2020 | Malik, S., Castellvi, Q., Becerra-Fajardo, L., Tudela-Pi, M., Garcia-Moreno, A., Shojaei Baghini, M., Ivorra, A. (2020). Injectable Sensors Based on Passive Rectification of Volume-Conducted Currents. IEEE Transactions on Biomedical Circuits and Systems, 14(4), (pp. 867-878), Link |
Injectable Temperature Sensors Based on Passive Rectification of Volume-Conducted Currents | 2021 | Becerra–Fajardo, L., García–Moreno, A., Llano, N. A. D. E., & Ivorra, A. (2021, October). Injectable Temperature Sensors Based on Passive Rectification of Volume-Conducted Currents. In 2021 IEEE Biomedical Circuits and Systems Conference (BioCAS) (pp. 01-06). IEEE. Link |
Volume conduction for powering deeply implanted networks of wireless injectable medical devices: a numerical parametric analysis | 2021 | Tudela-Pi, M., Minguillon, J., Becerra-Fajardo, L., & Ivorra, A. (2021). Volume conduction for powering deeply implanted networks of wireless injectable medical devices: a numerical parametric analysis. IEEE Access, 9, 100594-100605. Link |
Powering electronic implants by high frequency volume conduction: in human validation | 2022 | Minguillon, J., Tudela-Pi, M., Becerra-Fajardo, L., Perera-Bel, E., del-Ama, A. J., Gil-Agudo, Á., ... & Ivorra, A. (2022). Powering Electronic Implants by High Frequency Volume Conduction: In Human Validation". In IEEE Transactions on Biomedical Engineering, 2022. Link |
Floating EMG sensors and stimulators wirelessly powered and operated by volume conduction for networked neuroprosthetics | 2022 |
Becerra-Fajardo, L., Krob, M. O., Minguillon, J., Rodrigues, C., Welsch, C., Tudela-Pi, M., ... & Ivorra, A. (2022). Floating EMG sensors and stimulators wirelessly powered and operated by volume conduction for networked neuroprosthetics. Journal of NeuroEngineering and Rehabilitation, 19(1), 1-19. Link
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Wireless networks of injectable microelectronic stimulators based on rectification of volume conducted high frequency currents | 2022 | García-Moreno, A., Comerma-Montells, A., Tudela-Pi, M., Minguillon, J., Becerra-Fajardo, L., and Ivorra, A., Wireless networks of injectable microelectronic stimulators based on rectification of volume conducted high frequency currents. Journal of Neural Engineering, 19(5), Jan. 2022. Link |
Networks of Injectable Microdevices Powered and Digitally Linked by Volume Conduction for Neuroprosthetics: a Proof-of-Concept |
2023 | Becerra-Fajardo, L., Minguillon, J., Comerma, A., and Ivorra, A. Networks of Injectable Microdevices Powered and Digitally Linked by Volume Conduction for Neuroprosthetics: a Proof-of-Concept. In 2023 11th International IEEE/EMBS Conference on Neural Engineering (NER), pp. 1-4. IEEE, 2023. Link |
First-in-human demonstration of floating EMG sensors and stimulators wirelessly powered and operated by volume conduction | 2024 | Becerra-Fajardo, et al. First-in-human demonstration of floating EMG sensors and stimulators wirelessly powered and operated by volume conduction. Journal of NeuroEngineering and Rehabilitation, 21(1), 1-16. Jan 2024. Link |