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Chemical, Biological, Radiological & Explosive (CBRE) Detection and Protection. Dr. Clifford Lau ODUSD(LABS) 703-696-0371 [email protected] 27 January 2004. DoD Impact. Nanotechnology will enable warfighting capabilities. * Chem-bio warfare defense - PowerPoint PPT Presentation
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04/21/23 1
Chemical, Biological, Radiological & Explosive (CBRE)
Detection and Protection
Dr. Clifford LauODUSD(LABS)703-696-0371
27 January 2004
04/21/23 2
Nanotechnology will enable warfighting capabilities
* Chem-bio warfare defenseSensors with improved detection sensitivity and selectivity, decontamination
* Protective armors for the warriorStrong, light-weight bullet-stopping armors
* Reduction in weight of warfighting equipmentMiniaturization of sensors, computers, comm devices, and power supplies
* High performance platforms and weaponsGreater stealth, higher strength light-weight materials and structures
* High performance information technologyNanoelectronics for computers, memory, and information systems
* Energy and energetic materialsEnergetic nano-particles for fast release explosives and slow release propellants
* Uninhabited vehicles, miniature satellitesMiniaturization to reduce payload, increased endurance and range
DoD Impact
04/21/23 3
Why nanotechnology and CBRE?
• National and Homeland Security
• Weapons of Mass Destruction
• Chem/bio Warfare Defense
• Warfighter and first responder protection
• Nanostructures offer unprecedented potential Sensors with high sensitivity and selectivity
Protection, neutralization, and decontamination
04/21/23 4
Ultrasensitive and Selective Chip-Based Detection of DNAPrincipal Investigator: Chad A. Mirkin,Northwestern University
OBJECTIVES & DoD IMPACT Develop an experimental and theoretical understanding of
the physical and chemical properties of nanoparticle probes functionalized with biomolecules.
Engineer Chip-based biodetection platforms. Design and interface a state-of-the-art microfluidic and gel
separation system with the chip-based detection platforms. Create handheld biodetection systems for BWA’s, which do
not rely on PCR. Massive multiplexing capabilities. Field deployable, PCR-less identification of biowarfare and
terrorism agents.
APPROACH Develop novel detection schemes based on nanoparticle
probes to detect specific DNA sequences. Develop microfluidic systems to isolate cellular DNA
from complex biofluidic specimens. Integrate microfluidic purification, probe/target
assembly, and signal transduction features into a single analytical platform.
Investigate the fundamental basis of the selectivity of oligonucleotide-functionalized nanoparticles in chip-based formats using a combined experimental and theoretical approach.
Develop new DNA detection assays based upon metallic and semiconductor quantum dot particles.
TECHNICAL ACCOMPLISHMENTS Developed a novel approach, Biobarcode PCR, for ultrasensitive
protein detection. Developed a Raman labeling technique useful for DNA detection in
a random bead array format. Designed novel copolymer networks and separated proteins from
DNA in such networks via microchannel electrophoresis. Developed a technology for embedding micro magnetic stirrers in
Parylene surface micromachined channels. Developed a technology for making high-density valves and pumps
with pressure of membrane displacement 20kPa. Performed molecular simulations and determined the ion
distributions around duplex DNA, and dimers of duplex DNA molecules.
Developed a formally appropriate theory for capacitive charging that describes separate contributions of the DNA transport and the dot charging to the overall conductance.
04/21/23 5
• Chemical & biological sensors with improved sensitivity (single molecule) and specificity (no false positives)
• Explosives & mine detection
Single protein and nucleic acid molecules (e.g. aptamers and ion channels), single cells, nanoparticles, and nanostructured materials/devices are being characterized and employed for use as sensors of chemical and biological analytes, including use in the stochastic sensing mode that characterizes single molecular binding events.
Impact: Sensors to detect and identify unknown analytes.
NRL Nanobiosensors
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Biosensor Platforms
Piezoresistivecantilever
FABS
Transparent substrate with optical detection
FDB
Magnetoresistiveelements
BARCD.R. Baselt, et al., Proc. IEEE 85, 672 (1997)
G.U. Lee, et al., Anal. Biochem. 287, 261 (2000)
M.M. Miller, et al., J. Mag. Mag. Mat. 225, 138 (2001)
Force Discrimination Assay
Single Molecule Biosensors
04/21/23 8
Next Generation BARC(under development)
Next Generation BARC(under development)
Bead Array CounterLloyd Whitman, Naval Research Laboratory
Objective:• Develop optics-free DNA chip biosensor with enough sensitivity to eliminate need for PCR amplification
Payoff:• Combines state-of-the-art gene chip technology with NRL’s MRAM (magnetoresistive memory) program• Current BARC sensitivity is ~1800 molecules
• Current BARC chip has 64-sensing elements for multi-analyte detection
Transitions:• Advanced prototype (funded by TSWG) available in FY05
• NRL force discrimination assay/ biosensor technology under CRADA/ license negotiation by several companies
Concept:• Uses DNA-based hybridization assay to detect &
identify BW agents • But uses a magnetic bead to label the
hybridization reaction• Bound magnetic beads detected with embedded
magnetic sensor in the chip• Plan to add immunoassay on same chip
64-sensor BARC chip & next generation instrument
4.5 mm 200 µm
2 µm
J.C. Rife, et al., Sensors & Actuators A 107, 209 (2003)
04/21/23 10
Development of Biosensors for Detecting TNT in SeawaterHomme W. Hellinga, Duke University Medical Center
Objective:• Redesign the specificity of E. coli periplasmic binding proteins to bind TNT instead of their natural ligands.Approach:1. Members of the periplasmic binding protein family
have been engineered to incorporate fluorescent or electrochemical reporter groups
2. Computational techniques are used to predict the necessary mutations.
Accomplishments:• Three different receptors were successfully designed to bind TNT. One of these has a 1 nM dissociation constant, sufficient to detect TNT plume edges via UUV.• More thermostable receptors are being obtained through a combination of rational design and directed evolution.• Methods for immobilization onto surfaces are being refined.
TNT
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Stochastic Chemical Sensing MechanismsHagan Bayley, Texas A&M
Infinitely engineerable (e.g. M++ Site)
The Nanomachine: -Hemolysin Channel
Transiently bound analyte
blocks ion flow
Analytes + ion flow
Lipid bilayer
The Principle: Single Channel Ion Conductance Genetically Engineered M++ site
analyte-bound site
av av
Open site
pAmsec
Analyte Concentration = 1/kon [analyte] Analyte Signature = 1/koff
Issues Under Investigation Display options (supported
bilayers, nanotubular membranes) Interrogation (microwave, optical) Multi-valent oligosaccharide receptors Fluidics (M/NEMS)
Performance digital, information-rich output real chemical time, reagentless, self-calibrating large dynamic range, no signal loss large analyte universe
M,++ organics, proteins, DNA, (viruses)
Cd Zn Co Cd Zn CoCd
Ternary M++ Mixture
Transitions• Full patent filed• Commercial ventures planned• DoD Joint S&T Panel for CB Defense award
04/21/23 14
GOAL – Develop a multilayer film structure to simultaneously sense and destroy chemical and biological warfare agents.
Schematic Multilayer Scavenger and Sensor Device
Prof. John Yates, University of Pittsburgh
MURI: Photocatalytically Active Nanoscale Scavengers and Sensors for CW and Biological Agents
CHALLENGES –1. Integration of both chemical and biological agent sensors and CB catalysts for their destruction into stable multifunctional films or coatings 2. Efficient photocatalysis in the visible spectrum3. Integration of the multifunction films into working devices.
DELIVERABLES – •Polymer-anchored enzyme and antibody scavengers and sensors for CB agents
•Visible-light activated doped-TiO2 nanoparticles with non-photoreactive porous polymer support catalyzing the destruction of both chemical and biological agents
•Extremely active CaO and MgO and MgO-Cl2 nanoparticle material for the degradation of CB agents, supported in polymer films.
PRIOR WORK –•University of Pittsburgh research on TiO2 photocatalysts and polymer anchored enzymes and sensors.•Kansas State University work on active nanoparticle oxide adsorbents.•Texas A&M University work on antibody-based scavengers.
04/21/23 15
REACTIVE METAL OXIDE NANOPARTICLES
FOR SOLDIER PROTECTION Research Objective: Synthesis, characterization, and application of reactive metal oxide nanoparticles for protection against chemical and biological warfare agents and ballistic protection
Transitions: ARO program supports Professor Ken Klabunde at Kansas State University collaborating with ECBC Next Generation Sorbent Decontamination Program(FY09), Domestic Preparedness Office at SBCCOM, Reactive Protective Skin Cream program at USAMRICD, PM for Nonstockpile Chemical Demilitarization, Ballistic protection programs at Natick Soldier Center. R&D Partners: ARL-ARO/ECBC/NSC/USAMRICD/Universities/Industry
Payoff: Highly effective enhanced reactivity for the degradation of chemical and biological agents with reduced materiel burden. Enhanced Ballistic Protection for the soldier.
New Solutions for Decontamination and Protection of the Soldier in a Chemical and Biological Warfare Environment
—Surface area MgO
Commercially Available 30m2
Reactive Nanoparticles 500m2
•High Surface Area with increased
reactivity
04/21/23 16
CBRE Grand Challenge Workshop
• Workshop held on May 2-3, 2002 in Monterey, CA
• In conjunction with AVS meeting
• Attended by about 20 participants
• Goal was to recommend to NNI a plan of action aimed at realizing the promise of the CBRE grand challenge
• CBRE workshop report is available from NNCO
04/21/23 17
CBRE agents
•Botulinum Toxin•Diphtheria Toxin•Ricin•Anthrax•Smallpox•Nerve gas (VX, GX, mustard gas, sarin gas, etc.)•Blood agents (hydrogen cyanide, cyanogen chloride, etc.)•TNT•RDX•Plastic explosives•Plutonium•Dirty bombs•Many, many other agents
04/21/23 18
Lethality
• Lethal Dosage varies, but can be as low as 0.001 g/kg body weight
• Biological agents are more lethal due to self-replication in the body
• Body reaction time can vary from minutes to hours to days to months, depending on the agent
• Protection methods also vary
04/21/23 19
Detection
• Requirement for nerve agent detection threshold can vary, but can be as low as 0.001 mg/m3
• Required detection time can be as short as less than
10 seconds
• Difficult problems
Sensitivity Sample collection Liquid or airborne Selectivity False alarms Remote detection
04/21/23 20
Protection
• Filtration and Separation
Gas masks, HEPA filters, bullet vests, lead shields etc.
• Decontamination and neutralization
Reactive agents (e.g. MgO, Cl, etc.)
RF and plasma techniques
Catalytic nanostructures
• Mitigation
After attack
Envionmental issues
Cleansing of filters, sensors, etc.
04/21/23 21
Metrology and Instrumentation Needs
• Determination of lethality
• Are there other physical properties for detection?
• Sensitivity verification
ppm or ppb or ppt is not good enough
• Selectivity verification
Different strains of a virus
• Protection verification