Research

    Context and overall objectives of the project

    Brain pathologies are highly complex disorders. Despite recent progress, their prognosis is grim, defining a high societal challenge. Bridging life sciences, bio-nanotechnology, engineering and ICT, GLADIATOR promises a vanguard and comprehensive theranostic (therapeutic+diagnostic) solution for brain malignancies. GLADIATOR will provide, for the first time, a working prototype of a complete, autonomous and clinically applicable, nanonetwork-based, molecular communications system based on the conceptual framework of Externally Controllable Molecular Communications (ECMC). Using Glioblastoma Multiforme (GBM) tumors, the most detrimental of brain pathologies, as a proof-of-concept case, GLADIATOR will implement a platform of cell-based and electronic components, consisting of:

    1. Implantable autologous cell organoids, consisting of engineered induced neural stem cells (iNSCs), which will release specifically designed exosomal vesicles, acting as bio-nano-machines, delivering reprogramming (therapeutic) miRNAs and building nano-networks. Interfering with the underlying biological environment, they will provide a revolutionary intervention both killing the tumor cells but also reducing their aggressiveness and recurrence.
    2. A hybrid bio-electronic interface, consisting of coupled external and implantable devices, which will enable communication channels with fluorescent bio-nano-machines, released by the modified cancer cells, via micro-optoelectronic sensors.
    3. vA wireless ECMC network integrating the cellular, sub-cellular and electronic components. This system will autonomously monitor the spatiotemporal tumor evolution and recurrence and generate, on demand, appropriate reprogramming interventions, by increasing iNSC renewal and multiplication via external radiofrequency stimulation.

    GLADIATOR establishes the feasibility baseline and innovation potential towards a far-reaching transformation in the investigation and management of complex malignancies and potentially other major central nervous system pathologies. It also promotes the emerging supra-disciplines of “bio-nano-machine diagnostics” and a profound shift towards “nano-network therapeutics” which lay the grounds for future autonomous, closed-loop, externally controllable, micro- or nano- scale devices for disease management.

    Research Figure 1

    Representative images of neural stem cell (NSC) production: After 6 day cultivation of cell aggregates (so called embryoid bodies, EBs), the EBs are plated as neural stem cells starting with the passage number 0 in a Petri dish. Subsequent passages in cell-stage specific media enrich the NSC population and purifies the culture.

    Work performed in Year 1

    During the first year of the project, the consortium partners have worked towards the biological and technological goals of GLADIATOR:

    1. For the generation of the cellular components of the tumour recognising and reprogramming organoids, EPOS-Iasis, Ltd (EPOS) has investigated the direct induction of neural stem cells (iNSC) from readily available human fibroblasts from the Fraunhofer Institute for Biomedical Technology (FRAU) biobank. This method is based on a single, non-neuronal gene and is much safer for the patient. At the same time, to have a ‘hot start’ for robust and swift cell production for the experimental set up, FRAU has provided the consortium with iNSC derived from readily available pluripotent stem cells (iPSCs).
    2. In order to enable the construction of organoids, EPOS is also investigating hybrid scaffolds, combining the high surface area, morphology and porosity of electrospun fibers with the three-dimensional structure and swellable properties of hydrogel matrices in a single amalgamated 3-D structure, better mimics the mechanical properties and functions of the ECM.
    3. To externally control the biological components of the proposed system, the University of Oulu (UOULU) researchers have studied the effects of radio frequency (RF) exposure on cells, especially with regards to increased protein release from plasmids introduced in the cells. To further expand the understanding of these RF effects, EPOS and the University of Cyprus (UCY) are proceeding with a multi-parametric study to further elucidate the effect.
    4. The electronic implantable and wearable components of the project are being developed by the Waterford Institute of Technology (WIT), UCY, FRAU and the Norwegian University of Science and Technology (NTNU). The partners have performed thorough modelling and optimization of the hardware. Subsequently, they begun the construction of the optoelectronics for the implantable hybrid sensing devices and the ultrasound-based communication and power transfer hardware for the external wearable devices (patches).
    5. To facilitate the understanding and control of the molecular communications network, the WIT group is developing theoretical molecular communication models to investigate the actions of the exosome (EX) transmitters, the EX diffusion and binding to the receivers, and finally to integrate all models to create an end-to-end channel capacity and delay model for molecular communication via EXs.
    6. Simulated Specific Absorption Rate (SAR) of radiofrequency (RF) exposure inside the human head model.
      Research Figure 2

    Progress beyond the state of the art and potential impact

    The GLADIATOR consortium is already producing original research results beyond the state of the art. The partners have

    1. Proceeded with the formation of the cellular components of the proposed platform with a complete characterization of transdifferentiated cells and protocol optimisation, comparing the iNSC derived from iPSC and assessment of transfection efficacy in transdifferentiated iNSCs vs iPSC derived.
    2. Performed experiments to validate the effects of RF exposure on cells, and to study RF effects on the expression of fluorescent proteins under the control of various promoters. Increases in proliferation as well as protein production have already been demonstrated.
    3. Successfully demonstrated a sustainable three-dimensional (3D) scaffold comprised of biocompatible hydrogel and of electrospun nanofibers, as the technological embodiment of 3D GBM tumour constructs and the proposed organoids.
    4. Begun to introduce the first building blocks of a theoretical communication model, which include exosomal release distribution and binding, in an expanded molecular communications modelling platform.
    5. Developed the initial designs for novel technologies for ultrasound-based transcranial power transfer and passive communication schemes, which are currently being tested experimentally, as well as considering various designs of metasurfaces for transcranial RF transmission.

    When the proposed platform is completed and becomes clinically available, it is expected to have a significant societal impact. The advances in cancer management, enabled by the innovations in GLADIATOR, will improve patient prognosis and prolong survival by minimizing recurrences and reducing drug toxicity. Improved health, extended life expectancy and productivity, reduced sick-leaves, shorter hospitalizations, reduced return visits, less personnel and caregiver involvement will also have a positive effect on the already overstrained Health Care Systems.

    The ground-breaking biological and nanotechnology-based innovations of GLADIATOR, are also expected to have significant economic impact since they can enter into significant market segments as indicated by global market projections and underlying drivers. For example, the microelectronic medical implants and micro-sensors markets were valued at $35B in 2016 and expected to grow to $56B by 2021. The Point of Care (PoC) diagnosis market was valued at $10.3B in 2016 growing to $33.7B by 2025. GLADIATOR can lead to high-gain innovations that can have a long-lasting positive impact on Europe’s science and industry, with benefits proportional to the associated high-risks of the project.


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