Summary
Bio-hybrid machines (BHMs) combine living cell actuators with artificial materials in order to achieve greater autonomy, flexibility, and energy efficiency compared to standard robots. However, BHMs are developed in silos of individual research groups, making their development more of an art relying on individual knowledge, intuition, and skills than on standardized decision-making processes.
To push the manufacturing of BHMs towards bio-intelligent paradigm and model-based engineering, we propose to develop a self-monitoring and self-controlling manufacturing pipeline of BHMs. To realize such a pipeline, we would need to (i) Develop a modeling and simulation framework that will streamline the processes of design, quoting, manufacturing, verification, and reporting, thus significantly reducing error-prone manual steps. Also, given that actuators in BHMs are living cells, which greatly expands the parameter space, we believe that the development of BHMs would greatly benefit from AI-guided modeling process to optimize search for the most efficient design; (ii) To experimentally test, optimize, and verify the platform by developing a proof-of-principle reconfigurable modular catheter BHM; (iii) To group all necessary manufacturing equipment into an integrated bio-intelligent manufacturing cell (BIMC) and demonstrate its adaptable operation.
As a proof-of-principle, we will use BHM catheter as it is an innovative medical device that would be able to arrive into hard-to-reach regions of the human body and release drugs there.
To push the manufacturing of BHMs towards bio-intelligent paradigm and model-based engineering, we propose to develop a self-monitoring and self-controlling manufacturing pipeline of BHMs. To realize such a pipeline, we would need to (i) Develop a modeling and simulation framework that will streamline the processes of design, quoting, manufacturing, verification, and reporting, thus significantly reducing error-prone manual steps. Also, given that actuators in BHMs are living cells, which greatly expands the parameter space, we believe that the development of BHMs would greatly benefit from AI-guided modeling process to optimize search for the most efficient design; (ii) To experimentally test, optimize, and verify the platform by developing a proof-of-principle reconfigurable modular catheter BHM; (iii) To group all necessary manufacturing equipment into an integrated bio-intelligent manufacturing cell (BIMC) and demonstrate its adaptable operation.
As a proof-of-principle, we will use BHM catheter as it is an innovative medical device that would be able to arrive into hard-to-reach regions of the human body and release drugs there.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/101070328 |
| Start date: | 01-10-2022 |
| End date: | 30-09-2025 |
| Total budget - Public funding: | 3 978 056,93 Euro - 3 978 056,00 Euro |
Cordis data
Original description
Bio-hybrid machines (BHMs) combine living cell actuators with artificial materials in order to achieve greater autonomy, flexibility, and energy efficiency compared to standard robots. However, BHMs are developed in silos of individual research groups, making their development more of an art relying on individual knowledge, intuition, and skills than on standardized decision-making processes.To push the manufacturing of BHMs towards bio-intelligent paradigm and model-based engineering, we propose to develop a self-monitoring and self-controlling manufacturing pipeline of BHMs. To realize such a pipeline, we would need to (i) Develop a modeling and simulation framework that will streamline the processes of design, quoting, manufacturing, verification, and reporting, thus significantly reducing error-prone manual steps. Also, given that actuators in BHMs are living cells, which greatly expands the parameter space, we believe that the development of BHMs would greatly benefit from AI-guided modeling process to optimize search for the most efficient design; (ii) To experimentally test, optimize, and verify the platform by developing a proof-of-principle reconfigurable modular catheter BHM; (iii) To group all necessary manufacturing equipment into an integrated bio-intelligent manufacturing cell (BIMC) and demonstrate its adaptable operation.
As a proof-of-principle, we will use BHM catheter as it is an innovative medical device that would be able to arrive into hard-to-reach regions of the human body and release drugs there.
Status
SIGNEDCall topic
HORIZON-CL4-2021-DIGITAL-EMERGING-01-27Update Date
09-02-2023
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Organisations
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| UNIVERZITET U NOVOM SADU, POLJOPRIVREDNI FAKULTET NOVI SAD (Coördinator)
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| FUNDACIO INSTITUT DE BIOENGINYERIA DE CATALUNYA (IBEC)
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| LEVERETTE LANCE
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| SMART SENSING S.R.L.
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| Sant’Anna School of Advanced Studies - Scuola Superiore di Studi Universitari e di Perfezionamento...
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| UNIVERSITA DEGLI STUDI DI CAGLIARI (UNICA)
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| UNIVERSITY OF THE WEST OF ENGLAND, BRISTOL