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Future Implantable Systems

1 st Invitational Workshop on Body Area Network Technology and Applications June 20, 2011. Future Implantable Systems. Ada Poon Stanford University. Real Time, Distributed In Vivo Diagnostics . Intracardiac Electrogram. Moving implants Wireless endocardial pacing and sensing.

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Future Implantable Systems

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  1. 1st Invitational Workshop on Body Area Network Technology and Applications June 20, 2011 Future Implantable Systems Ada Poon Stanford University

  2. Real Time, Distributed In Vivo Diagnostics Intracardiac Electrogram • Moving implants • Wireless endocardial pacing and sensing • Multielectrode epicardial mapping for EP study • Chip in cell for cellular-level monitoring and therapeutic treatments 10 mm 100 mm 1 mm Implant Dimension

  3. Current Autonomous Implants Retinal implant Cochlear implant Endoscope [Lenaerts 07] [Wang 06] • Use remote power source to remove the battery partially or completely. • Power transmission is like a transformer –inductive coupling. • Power receiver is large – 1 to a few cm. • Extremely short distance (almost touching) • Coil alignment is critical. • Still, we haven’t solved the problem of miniaturization.

  4. Can we do better than inductive coupling? Back to Physics … In the past 50 years, analyses on wireless power transmission within biological tissues omit the displacement current− the term Maxwell added to Ampere’s Law and resulted in the Maxwell equations. • Lower frequency is better! • Most systems operate at 10 MHz or lower. YES when we take into account the displacement current.

  5. Optimal frequency is in the GHz-range!

  6. Prototype Receiver at .13 m CMOS ISSCC 09 • Unique features • Adaptive conjugate matching • Highly efficient rectifier • Coil dimension is 2 mm × 2 mm which is 100 times smaller than previous designs in the literature at the same power transfer efficiency and range.

  7. 1959, Richard Feynman, Plenty of Room at the Bottom:

  8. Translating Torques into Motion Top View • Idea is similar to the paddle in kayaking. • Asymmetrical shape produces asymmetrical drag forces. • Alternate direction of EM torque results in net forward force. • Device can be optimized in terms of shape, frequency of current switching, and magnitudes of currents. Small Drag Force Current Loop Reverse Current EM Torque Net Force Net Force Large Drag Force

  9. Preliminary Experiments

  10. System-Level Block Diagram Implantable Device • Power and data are transmitted from same antenna • Propulsion dominates power consumption, and must be efficient. • Plan to tape out in mid June Vcc Rectifier (Power Supply) Transmitter Power Data Demodulation (downlink) Controller Unit Propulsion System Data (mod and demod) Load Modulation (uplink) Functional Units/Sensors/etc

  11. Wireless Probing of the Heart In the United States, about half of the cardiac mortality is due to ventricular arrhythmia, which accounts for approximately 300,000 deaths per year. Intracardiac Electrogram

  12. CHIC (CHip In Cell) • Autonomous, wireless, implantable sensor • Active, continuous-time monitor of cellular activity Lung cancer cell Source: T. Johnson, B. Reutter 25 μm2 chip 50 μm DETECTIONSYSTEM

  13. Sensors and Resonantors CMFETchemical sensor Pressure sensor on flexible substrate 5 µm Micro resonantor

  14. Choice of Cells Cell Type Cell Size Device Size 1.0 mm (spherical) 50 mm XenopusOocytes Xenopus.com 60 mm (spherical) Plant Protoplasts 10-15 mm “Plant Physiology”, 5th ed. Chinese Hamster Ovary (CHO) 2x 25x 100 mm (spread on surface) ~ 5 mm

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