Bio


Bioelectronics, neurostimulation, biosensors, conducting polymers, microfabrication.

Stanford Advisors


All Publications


  • The impact of hydrogen peroxide production in OECTs for <i>in vitro</i> applications JOURNAL OF MATERIALS CHEMISTRY C Lubrano, C., Bettucci, O., Dijk, G., Salleo, A., Giovannitti, A., Santoro, F. 2023

    View details for DOI 10.1039/d3tc02849f

    View details for Web of Science ID 001144727300001

  • PEDOT:PSS-coated platinum electrodes for neural stimulation. APL bioengineering Dijk, G., Pas, J., Markovic, K., Scancar, J., O'Connor, R. P. 2023; 7 (4): 046117

    Abstract

    Safe and long-term electrical stimulation of neurons requires charge injection without damaging the electrode and tissue. A common strategy to diminish adverse effects includes the modification of electrodes with materials that increases the charge injection capacity. Due to its high capacitance, the conducting polymer PEDOT:PSS is a promising coating material; however, the neural stimulation performance in terms of stability and safety remains largely unexplored. Here, PEDOT:PSS-coated platinum (Pt-PEDOT:PSS) microelectrodes are examined for neural stimulation and compared to bare platinum (Pt) electrodes. Microelectrodes in a bipolar configuration are used to deliver current-controlled, biphasic pulses with charge densities ranging from 64 to 255 μC cm-2. Stimulation for 2 h deteriorates bare Pt electrodes through corrosion, whereas the PEDOT:PSS coating prevents dissolution of Pt and shows no degradation. Acute stimulation of primary cortical cells cultured as neurospheres shows similar dependency on charge density for Pt and Pt-PEDOT:PSS electrodes with a threshold of 127 μC cm-2 and increased calcium response for higher charge densities. Continuous stimulation for 2 h results in higher levels of cell survival for Pt-PEDOT:PSS electrodes. Reduced cell survival on Pt electrodes is most profound for neurospheres in proximity of the electrodes. Extending the stimulation duration to 6 h increases cell death for both types of electrodes; however, neurospheres on Pt-PEDOT:PSS devices still show significant viability whereas stimulation is fatal for nearly all cells close to the Pt electrodes. This work demonstrates the protective properties of PEDOT:PSS that can be used as a promising approach to extend electrode lifetime and reduce cell damage for safe and long-term neural stimulation.

    View details for DOI 10.1063/5.0153094

    View details for PubMedID 38075207

    View details for PubMedCentralID PMC10699886

  • Fabrication and in vivo 2-photon microscopy validation of transparent PEDOT:PSS microelectrode arrays. Microsystems & nanoengineering Dijk, G., Kaszas, A., Pas, J., O'Connor, R. P. 2022; 8: 90

    Abstract

    Transparent microelectrode arrays enable simultaneous electrical recording and optical imaging of neuronal networks in the brain. Electrodes made of the conducting polymer poly(3,4-ethylenedioxythiophene) doped with polystyrene sulfonate (PEDOT:PSS) are transparent; however, device fabrication necessitates specific processes to avoid deterioration of the organic material. Here, we present an innovative fabrication scheme for a neural probe that consists of transparent PEDOT:PSS electrodes and demonstrate its compatibility with 2-photon microscopy. The electrodes show suitable impedance to record local field potentials from the cortex of mice and sufficient transparency to visualize GCaMP6f-expressing neurons underneath the PEDOT:PSS features. The results validate the performance of the neural probe, which paves the way to study the complex dynamics of in vivo neuronal activity with both a high spatial and temporal resolution to better understand the brain.

    View details for DOI 10.1038/s41378-022-00434-7

    View details for PubMedID 36051746

    View details for PubMedCentralID PMC9424218

  • Electroporation Microchip With Integrated Conducting Polymer Electrode Array for Highly Sensitive Impedance Measurement IEEE TRANSACTIONS ON BIOMEDICAL ENGINEERING Dijk, G., Poulkouras, R., OConnor, R. P. 2022; 69 (7): 2363-2369

    Abstract

    Monitoring of impedance changes during electroporation-based treatments can be used to study the biological response and provide feedback regarding treatment progression. However, seamless integration of the sensing electrodes with the setup can be challenging and high impedance sensing electrodes limit the recording sensitivity as well as the spatial resolution. Here, we present an all-in-one microchip containing stimulation electrodes, as well as an array of low impedance, micro-scale sensing electrodes for highly sensitive impedance monitoring.An in vitro platform is fabricated with integrated stimulation and sensing electrodes. To reduce the impedance, the sensing electrodes are coated with the conducting polymer PEDOT:PSS. The performance is studied during the growth of a confluent cell layer and treatment with electrical pulses.Coated electrodes, compared to uncoated electrodes, show more pronounced impedance changes in a broader frequency range throughout the formation of a confluent cell layer and after electrical treatment.PEDOT:PSS coatings enhance the monitoring of impedance changes with micro-scale electrodes, enabling high spatial resolution and increased sensitivity.Such monitoring systems can be used to study electroporation dynamics and monitor treatment progression for better understanding of underlying mechanisms and improved outcomes.

    View details for DOI 10.1109/TBME.2022.3143542

    View details for Web of Science ID 000812532300029

    View details for PubMedID 35041593

  • PEDOT:PSS-Coated Stimulation Electrodes Attenuate Irreversible Electrochemical Events and Reduce Cell Electropermeabilization ADVANCED MATERIALS INTERFACES Dijk, G., Ruigrok, H. J., O'Connor, R. P. 2021; 8 (19)
  • Influence of PEDOT:PSS Coating Thickness on the Performance of Stimulation Electrodes ADVANCED MATERIALS INTERFACES Dijk, G., Ruigrok, H. J., O'Connor, R. P. 2020; 7 (16)
  • Stability of PEDOT:PSS-Coated Gold Electrodes in Cell Culture Conditions ADVANCED MATERIALS TECHNOLOGIES Dijk, G., Rutz, A. L., Malliaras, G. G. 2020; 5 (3)