High-Density Flexible Electrode Arrays for Next-Generation Brain-Computer Interfaces

Rachel Kim1, Marcus Lindqvist2, Hao Zheng3
1 Department of Bioengineering, Stanford University, Stanford, CA 94305, USA
2 Neuroscience Institute, Karolinska Institutet, 171 77 Stockholm, Sweden
3 School of Microelectronics, Fudan University, Shanghai 200433, China
Published: 2026-05-28 · GAST Vol. 1, No. 1 (2026)

Abstract

Brain-computer interfaces (BCIs) require electrode arrays that simultaneously achieve high spatial resolution, mechanical compliance, and long-term biocompatibility. We fabricate ultra-flexible, high-density microelectrode arrays (HD-MEAs) with 1,024 channels on a 4 μm-thick parylene-C substrate using photolithography and lift-off metallization. The arrays conform to cortical surface curvature with <5% impedance increase after 10,000 bending cycles at 5 mm radius. In vivo recordings from macaque motor cortex demonstrate single-unit resolution across 256 simultaneously active channels, with signal-to-noise ratio (SNR) of 4.8 ± 0.6. A wireless headstage transmits neural data at 30 Mbps with 24-hour battery life, enabling untethered BCI operation for motor prosthesis control applications.

Keywords: brain-computer interface, microelectrode arrays, flexible electronics, neural recording, motor cortex

1. Introduction

Brain-computer interfaces translate neural activity into control signals for external devices, offering transformative potential for individuals with paralysis and neurodegenerative diseases. Utah arrays and Neuropixels probes have advanced intracortical recording capabilities but suffer from mechanical mismatch with brain tissue, leading to glial scarring and signal degradation over months. Flexible, conformable electrode arrays address this challenge by reducing micromotion-induced tissue damage.

Recent progress in soft microelectronics has enabled electrode arrays with channel counts exceeding 256 while maintaining sub-10 μm substrate thickness. However, achieving reliable high-density routing, low-impedance contacts, and wireless data transmission in a clinically translatable form factor remains an open engineering challenge.

2. Device Fabrication and Characterization

HD-MEAs were fabricated on 4-inch silicon wafer carriers using a multi-layer process: (1) parylene-C deposition (4 μm), (2) Ti/Pt/Au (10/100/200 nm) electrode patterning by photolithography, (3) PEDOT:PSS coating for impedance reduction, and (4) parylene-C encapsulation with laser-ablated recording windows (30 μm diameter). Interconnect pitch was 100 μm with 32:1 multiplexing to a custom CMOS readout ASIC.

Table 1. Electrochemical and mechanical properties of HD-MEA electrodes before and after PEDOT:PSS coating

PropertyBare PtPEDOT:PSS CoatedSpecification
Impedance @ 1 kHz842 ± 95 kΩ48 ± 8 kΩ< 100 kΩ
Phase @ 1 kHz−62°−18°−45° to 0°
Charge storage capacity0.8 mC/cm²12.4 mC/cm²> 2 mC/cm²
Bending cycles (5 mm r)> 10,000> 1,000
Channel count1,024≥ 256

3. In Vivo Neural Recording Performance

Chronic implantation studies were conducted in two macaques performing a center-out reaching task. HD-MEAs were placed on the surface of primary motor cortex (M1) and connected to a wireless headstage (30 Mbps, 2.4 GHz). Single-unit activity was resolved on 256 ± 18 channels per session over 6 months of recording.

4.510.416.322.128SNRSingle Units (×10)04812162026Weeks Post-ImplantSNR / Single Units (×10)
Figure 1. Signal-to-noise ratio (SNR) and number of resolved single units over 26 weeks of chronic HD-MEA implantation in macaque M1
5262.57383.594151015202530Training DayDecoding Accuracy (%)
Figure 2. Motor decoding accuracy (% correct) for 2D cursor control using HD-MEA neural signals with a Kalman filter decoder

Table 2. Comparison of HD-MEA performance with state-of-the-art BCI electrode technologies

TechnologyChannelsSNRChronic StabilityWireless
This work (HD-MEA)1,0244.826 weeksYes
Neuropixels 2.03845.512 weeksNo
Utah Array964.252 weeksYes
ECoG Grid2562.1104 weeksYes

4. Conclusions

High-density flexible electrode arrays with 1,024 channels, wireless telemetry, and demonstrated chronic stability represent a significant advance toward clinically viable BCIs. The combination of single-unit resolution, mechanical compliance, and untethered operation addresses key barriers to translation. Ongoing work focuses on fully implantable systems with inductive power transfer and closed-loop stimulation capabilities for bidirectional neural interfaces.

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