Biologically-derived Materials for Powering Next Generation Biomedical … · 2018-07-13 ·...

Biologically-derived Materials for Powering

Next Generation Biomedical Electronics

Young Jo Kim, Ph.D. Assistant Professor

Department of Chemical Engineering

University of New Hampshire

Implantable biomedical devices

Stimulate deep brain for treating obesity

Tissue

stimulation Biosensor

Monitor pH, T, and glucose

Controlled

release

Deliver drugs

Challenges with implantable devices

Infection

Chronic inflammation

Costly surgeries

Replace batteries

Reduce infection risk

Temporary

Cost-effective deployment

What if we could build the devices…

Most people feel comfortable with taking pills.

Why Edible Electronics?

Balance of functional device lifetime with rapid deployment

Non-invasive, high patient compliance

Reduced sterilization burden

Obviate issues associated with chronic implants

Helius (Proteus Biomedical)

PillCam (Given Imaging)

Indication Monitor compliance Non-invasive imaging

Function Trigger, communication Image acquisition, transfer

Device lifetime ~10 min ~8 hr

Power source Mg-Cu galvanic cell 2 x 1.5V Ag2O batteries

Logic elements Silicon Silicon

Packaging None Polycarbonate

Size (D x L) 2 mm x 2 mm 11 mm x 26 mm

Mass 0.003 g 3.45 g

Retention risk 0.001% 1.47%

www.proteus.com

www.givenimaging.com

Device comparison

Edible Battery

Anode Activated carbon Cathode

Electrically- conductive elastomer

• Made of edible materials • Temporary • Non-invasive

operated by Na+ in gastric fluid

Reliability

+ Long operational lifetimes

+ Robust performance

+ Manufacturing

Safety

+ Possible bioabsorption

+ Reduced risk of event

+ Materials of known risk

Ideal electrodes for edible electronics

Inspired by Cuttlefish Ink…

Inspired by cuttlefish ink

10 mm 0.5 mm

Eumelanins from cuttlefish (sepia officinalis)

• Homogeneous nanostructure (diameter= ~100nm)

• Stable (non-soluble) in aqueous solution

• Hydration dependent electronic-ionic hybrid conductivity

Eumelanins in multi-scale

Activated carbon anode MnO2 cathode

Melanin anode MnO2 cathode

Is eumelanin a viable solution?

Specific Capacity (mAh/g)

Specific Capacity (mAh/g) 10 20

Can we tune the capacity?

Synthetic Melanin Electrode

[P1801-02]

Thank you

Biologically-derived Materials for Powering Next Generation Biomedical … · 2018-07-13 ·...

Documents

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Intergranular pitting corrosion of CoCrMo biomedical ... · The CoCrMo alloy has been approved as an implantable biomedical material since the 1970s.2 Advantages of using a metal

enabling low-cost, MEMS and implantable biomedical systemsadriaens/Site/UM_CleanTech_files/... · 2009-09-10 · implantable biomedical systems - reduced size: 32g/28cm3 - longer

High-performance flexible and broadband photodetectors ...displays, wearable ultraviolet radiation monitoring, and implantable biomedical devices, etc. [10–12]. Many kinds of flexible

Implantable Energy‐Harvesting Devices13901785.s21d-13.faiusrd.com/61/ABUIABA9GAAglMXk2gUowL7... · Biomedical Engineering, Beihang University. His research work is focusing on nanogenerators,

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Photovoltaic Power Harvesting Technologies in Biomedical ... · iomedical implantable and wearable devices play a significant role in modern therapy and diagnosis [1]. Due to their

A Review of Implantable Antennas for Wireless Biomedical ... · PDF fileimplantable antennas for wireless biomedical devices is ... communication to an implantable device or sensor

089 ' # '6& *#0 & 7 · useful for biomedical devices. The power supply module for biomedical implantable devices is the core technology among them. Conventionally, batteries or wired

Body-Motion Driven MEMS Generator for Implantable Biomedical … · 2007-05-23 · Implantable Biomedical Devices Jose Martinez-Quijada, Sazzadur Chowdhury Research Centre for Integrated

Wearable and Implantable Sensors for Biomedical Applications · Annual Rev. Anal. Chem. 2018.11. Downloaded from Access provided by University of California - Los Angeles UCLA on

Research Article ASelf ...downloads.hindawi.com/journals/jamop/2012/963187.pdf · Implantable wireless devices may allow localized real-time biomedical treating and monitoring. However,

TETS for Powering Implantable Biomedical Devices T. Dissanayake, D. Budgett, A.P. Hu, S. Malpas and L. Bennet

2018 BIOMEDICAL TOPICS - University of Sydneyweb.aeromech.usyd.edu.au/AMME4111/2018 Thesis... · biomedical implantable devices and sensingThis project will inv. estigate the potential

IMPLANTABLE FERRITE ANTENNA FOR BIOMEDICAL …

Wearable and implantable packaging for biomedical devicesthor.inemi.org/webdownload/newsroom/Presentations/Med_Pkg_Sept20… · Wearable and implantable packaging for biomedical devices

Biologically Inspired Object Localization for a …clbme.bas.bg/bioautomation/2005/vol_3.1/files/3_3.2.pdfZlatogor Minchev Centre of Biomedical Engineering “Prof. Ivan Daskalov”–

BIOMATERIALS, IMPLANTABLE MEDICAL DEVICES AND BIOMEDICAL SCIENCE: