Corticale creates unique neural technologies for next generation of Brain Computer Interfaces for the treatment of motor and speech brain-related diseases
Modular
our UHD BCI permits the implantation of multiple SiNAPS probes, each equipped with 1024 neural sensors, enabling the sampling of broad brain areas at the resolution of individual neurons
Minimally invasive
Each probe measures less than 100 x 50 micrometers, enabling low-risk brain surgery and ensuring stable interfacing for extended periods
Bidirectional
our neural probes include dedicated stimulation sites that enable the bidirectional communication with the brain
Wireless
our patented wireless technology allows for low-power Ultra Wide Band (UWB) transmission of high density neural data stream (600Mbit/s)
Adaptive
We are creating highly efficient and personalized AI/ML algorithms to interpret the massive information content peculiar of our unique neural implant into commands for controlling external devices, such as assistive technologies or peripheral prosthetics
High-Density
Our neural probes are made up of high-density electrode arrays that allow for the capture of the most detailed view of brain activity ever achieved by a neural implant
Modular
our UHD BCI permits the implantation of multiple SiNAPS probes, each equipped with 1024 neural sensors, enabling the sampling of broad brain areas at the resolution of individual neurons
Minimally invasive
Each probe measures less than 100 x 50 micrometers, enabling low-risk brain surgery and ensuring stable interfacing for extended periods
Bidirectional
our neural probes include dedicated stimulation sites that enable the bidirectional communication with the brain
Wireless
our patented wireless technology allows for low-power Ultra Wide Band (UWB) transmission of high density neural data stream (600Mbit/s)
Adaptive
We are creating highly efficient and personalized AI/ML algorithms to interpret the massive information content peculiar of our unique neural implant into commands for controlling external devices, such as assistive technologies or peripheral prosthetics
High-Density
Our neural probes are made up of high-density electrode arrays that allow for the capture of the most detailed view of brain activity ever achieved by a neural implant
Modular
our UHD BCI permits the implantation of multiple SiNAPS probes, each equipped with 1024 neural sensors, enabling the sampling of broad brain areas at the resolution of individual neurons
Minimally invasive
Each probe measures less than 100 x 50 micrometers, enabling low-risk brain surgery and ensuring stable interfacing for extended periods
Bidirectional
our neural probes include dedicated stimulation sites that enable the bidirectional communication with the brain
Wireless
our patented wireless technology allows for low-power Ultra Wide Band (UWB) transmission of high density neural data stream (600Mbit/s)
Adaptive
We are creating highly efficient and personalized AI/ML algorithms to interpret the massive information content peculiar of our unique neural implant into commands for controlling external devices, such as assistive technologies or peripheral prosthetics
High-Density
Our neural probes are made up of high-density electrode arrays that allow for the capture of the most detailed view of brain activity ever achieved by a neural implant
Modular
our UHD BCI permits the implantation of multiple SiNAPS probes, each equipped with 1024 neural sensors, enabling the sampling of broad brain areas at the resolution of individual neurons
Minimally invasive
Each probe measures less than 100 x 50 micrometers, enabling low-risk brain surgery and ensuring stable interfacing for extended periods
Bidirectional
our neural probes include dedicated stimulation sites that enable the bidirectional communication with the brain
Wireless
our patented wireless technology allows for low-power Ultra Wide Band (UWB) transmission of high density neural data stream (600Mbit/s)
Adaptive
We are creating highly efficient and personalized AI/ML algorithms to interpret the massive information content peculiar of our unique neural implant into commands for controlling external devices, such as assistive technologies or peripheral prosthetics
High-Density
Our neural probes are made up of high-density electrode arrays that allow for the capture of the most detailed view of brain activity ever achieved by a neural implant
Modular
our UHD BCI permits the implantation of multiple SiNAPS probes, each equipped with 1024 neural sensors, enabling the sampling of broad brain areas at the resolution of individual neurons
Minimally invasive
Each probe measures less than 100 x 50 micrometers, enabling low-risk brain surgery and ensuring stable interfacing for extended periods
Bidirectional
our neural probes include dedicated stimulation sites that enable the bidirectional communication with the brain
Wireless
our patented wireless technology allows for low-power Ultra Wide Band (UWB) transmission of high density neural data stream (600Mbit/s)
Adaptive
We are creating highly efficient and personalized AI/ML algorithms to interpret the massive information content peculiar of our unique neural implant into commands for controlling external devices, such as assistive technologies or peripheral prosthetics
High-Density
Our neural probes are made up of high-density electrode arrays that allow for the capture of the most detailed view of brain activity ever achieved by a neural implant
Modular
our UHD BCI permits the implantation of multiple SiNAPS probes, each equipped with 1024 neural sensors, enabling the sampling of broad brain areas at the resolution of individual neurons
Minimally invasive
Each probe measures less than 100 x 50 micrometers, enabling low-risk brain surgery and ensuring stable interfacing for extended periods
Bidirectional
our neural probes include dedicated stimulation sites that enable the bidirectional communication with the brain
Wireless
our patented wireless technology allows for low-power Ultra Wide Band (UWB) transmission of high density neural data stream (600Mbit/s)
Adaptive
We are creating highly efficient and personalized AI/ML algorithms to interpret the massive information content peculiar of our unique neural implant into commands for controlling external devices, such as assistive technologies or peripheral prosthetics
High-Density
Our neural probes are made up of high-density electrode arrays that allow for the capture of the most detailed view of brain activity ever achieved by a neural implant
Modular
our UHD BCI permits the implantation of multiple SiNAPS probes, each equipped with 1024 neural sensors, enabling the sampling of broad brain areas at the resolution of individual neurons
Minimally invasive
Each probe measures less than 100 x 50 micrometers, enabling low-risk brain surgery and ensuring stable interfacing for extended periods
Bidirectional
our neural probes include dedicated stimulation sites that enable the bidirectional communication with the brain
Wireless
our patented wireless technology allows for low-power Ultra Wide Band (UWB) transmission of high density neural data stream (600Mbit/s)
Adaptive
We are creating highly efficient and personalized AI/ML algorithms to interpret the massive information content peculiar of our unique neural implant into commands for controlling external devices, such as assistive technologies or peripheral prosthetics
High-Density
Our neural probes are made up of high-density electrode arrays that allow for the capture of the most detailed view of brain activity ever achieved by a neural implant
Modular
our UHD BCI permits the implantation of multiple SiNAPS probes, each equipped with 1024 neural sensors, enabling the sampling of broad brain areas at the resolution of individual neurons
Minimally invasive
Each probe measures less than 100 x 50 micrometers, enabling low-risk brain surgery and ensuring stable interfacing for extended periods
Bidirectional
our neural probes include dedicated stimulation sites that enable the bidirectional communication with the brain
Wireless
our patented wireless technology allows for low-power Ultra Wide Band (UWB) transmission of high density neural data stream (600Mbit/s)
Adaptive
We are creating highly efficient and personalized AI/ML algorithms to interpret the massive information content peculiar of our unique neural implant into commands for controlling external devices, such as assistive technologies or peripheral prosthetics
High-Density
Our neural probes are made up of high-density electrode arrays that allow for the capture of the most detailed view of brain activity ever achieved by a neural implant
Corticale creates unique neural technologies for next generation of Brain Computer Interfaces for the treatment of motor and speech brain-related diseases
Modular
our UHD BCI permits the implantation of multiple SiNAPS probes, each equipped with 1024 neural sensors, enabling the sampling of broad brain areas at the resolution of individual neurons
Minimally invasive
Each probe measures less than 100 x 50 micrometers, enabling low-risk brain surgery and ensuring stable interfacing for extended periods
Bidirectional
our neural probes include dedicated stimulation sites that enable the bidirectional communication with the brain
Wireless
our patented wireless technology allows for low-power Ultra Wide Band (UWB) transmission of high density neural data stream (600Mbit/s)
Adaptive
We are creating highly efficient and personalized AI/ML algorithms to interpret the massive information content peculiar of our unique neural implant into commands for controlling external devices, such as assistive technologies or peripheral prosthetics
High-Density
Our neural probes are made up of high-density electrode arrays that allow for the capture of the most detailed view of brain activity ever achieved by a neural implant
Modular
our UHD BCI permits the implantation of multiple SiNAPS probes, each equipped with 1024 neural sensors, enabling the sampling of broad brain areas at the resolution of individual neurons
Minimally invasive
Each probe measures less than 100 x 50 micrometers, enabling low-risk brain surgery and ensuring stable interfacing for extended periods
Bidirectional
our neural probes include dedicated stimulation sites that enable the bidirectional communication with the brain
Wireless
our patented wireless technology allows for low-power Ultra Wide Band (UWB) transmission of high density neural data stream (600Mbit/s)
Adaptive
We are creating highly efficient and personalized AI/ML algorithms to interpret the massive information content peculiar of our unique neural implant into commands for controlling external devices, such as assistive technologies or peripheral prosthetics
High-Density
Our neural probes are made up of high-density electrode arrays that allow for the capture of the most detailed view of brain activity ever achieved by a neural implant
Modular
our UHD BCI permits the implantation of multiple SiNAPS probes, each equipped with 1024 neural sensors, enabling the sampling of broad brain areas at the resolution of individual neurons
Minimally invasive
Each probe measures less than 100 x 50 micrometers, enabling low-risk brain surgery and ensuring stable interfacing for extended periods
Bidirectional
our neural probes include dedicated stimulation sites that enable the bidirectional communication with the brain
Wireless
our patented wireless technology allows for low-power Ultra Wide Band (UWB) transmission of high density neural data stream (600Mbit/s)
Adaptive
We are creating highly efficient and personalized AI/ML algorithms to interpret the massive information content peculiar of our unique neural implant into commands for controlling external devices, such as assistive technologies or peripheral prosthetics
High-Density
Our neural probes are made up of high-density electrode arrays that allow for the capture of the most detailed view of brain activity ever achieved by a neural implant
Modular
our UHD BCI permits the implantation of multiple SiNAPS probes, each equipped with 1024 neural sensors, enabling the sampling of broad brain areas at the resolution of individual neurons
Minimally invasive
Each probe measures less than 100 x 50 micrometers, enabling low-risk brain surgery and ensuring stable interfacing for extended periods
Bidirectional
our neural probes include dedicated stimulation sites that enable the bidirectional communication with the brain
Wireless
our patented wireless technology allows for low-power Ultra Wide Band (UWB) transmission of high density neural data stream (600Mbit/s)
Adaptive
We are creating highly efficient and personalized AI/ML algorithms to interpret the massive information content peculiar of our unique neural implant into commands for controlling external devices, such as assistive technologies or peripheral prosthetics
High-Density
Our neural probes are made up of high-density electrode arrays that allow for the capture of the most detailed view of brain activity ever achieved by a neural implant
Corticale offers the most advanced scalable
technology for flexible and reliable communication with the brain
Corticale offers the most advanced scalable
technology for flexible and reliable communication with the brain
Thanks to the unique capability of our brain implant to simultaneously interact with thousands of individual neurons and brain circuitries distributed across wide brain areas, our technology provides the highest informative content ever provided to an AI-based neural decoder.
This allows overcoming the limitations of current BCIs, enabling a big leap in decoding performance, robustness, and stability, thus improving the efficacy of neural implants for the treatment of people affected brain-realated diseases.
Thanks to the unique capability of our brain implant to simultaneously interact with thousands of individual neurons and brain circuitries distributed across wide brain areas, our technology provides the highest informative content ever provided to an AI-based neural decoder.
This allows overcoming the limitations of current BCIs, enabling a big leap in decoding performance, robustness, and stability, thus improving the efficacy of neural implants for the treatment of people affected brain-realated diseases.
Biocompatible device encapsulation ———
UWB wireless data transmission —————
Device Battery —————————————
Neural Data Processor —————————-
Inteconnecting Stage ——————————
X64
neural sensors per penetrating thread than state of the art BCI
X85
higher electrode array density than standard neural interface
X100
smaller dimension than standard clinical SEEG electrodes
Biocompatible device encapsulation
UWB wireless data transmission
Device Battery
Neural Data Processor
Inteconnecting Stage
X64
neural sensors per penetrating thread than state of the art BCI
X85
higher electrode array density than standard neural interface
X100
smaller dimension than standard clinical SEEG electrodes
An unprecedent level of details
An unprecedent level of details
Thanks to a modular approach in which each implant enables the collection of data coming from hundreds of neural sensors organized in high-density arrays, we are able to map brain activity with a resolution never seen before.
Each person is different and only by observing every single detail of their brain activity is it possible to create personalized BCIs that naturally and intuitively adapt to each individual.
Thanks to a modular approach in which each implant enables the collection of data coming from hundreds of neural sensors organized in high-density arrays, we are able to map brain activity with a resolution never seen before.
Each person is different and only by observing every single detail of their brain activity is it possible to create personalized BCIs that naturally and intuitively adapt to each individual.
Corticale HD BCI's data resolution
Corticale HD BCI's data resolution
Standard's data resolution
Standard's data resolution
Progetto cofinanziato con risorse del PR FESR Liguria 2021/2027
Programma Regionale PR FESR Liguria 2021/2027 – Obiettivo Specifico 1.2. “Permettere ai cittadini, alle impese, alle organizzazioni di ricerca e alle autorità pubbliche di cogliere i vantaggi della digitalizzazione” – Azione 1.2.3 “Sostenere l’introduzione di pratiche e tecnologie digitali nelle imprese” – Bando “Supporto allo sviluppo di progetti di digitalizzazione nelle micro, piccole e medie imprese” – Anno 2024.
Via Pietro Chiesa 9
16149 Genova, Italy
Phone: +39 010 8595211
Email: info@corticale.com
Privacy Policy
Cookie Policy
Grants & Incentives
Quality Policy
Progetto cofinanziato con risorse del PR FESR Liguria 2021/2027
Programma Regionale PR FESR Liguria 2021/2027 – Obiettivo Specifico 1.2. “Permettere ai cittadini, alle impese, alle organizzazioni di ricerca e alle autorità pubbliche di cogliere i vantaggi della digitalizzazione” – Azione 1.2.3 “Sostenere l’introduzione di pratiche e tecnologie digitali nelle imprese” – Bando “Supporto allo sviluppo di progetti di digitalizzazione nelle micro, piccole e medie imprese” – Anno 2024.
Via Pietro Chiesa 9
16149 Genova, Italy
Phone: +39 010 8595211
Email: info@corticale.com
Privacy Policy
Cookie Policy
Grants & Incentives
Quality Policy