https://quantomics.netlify.app/tags/nanotechnology/NanotechnologyHugo Blox Builder (https://hugoblox.com)en© 2026 QuantOmics NSERC CREATE ProgramWed, 01 Jan 2025 00:00:00 +0000https://quantomics.netlify.app/media/icon_hu11734318148517933569.pnghttps://quantomics.netlify.app/tags/nanotechnology/https://quantomics.netlify.app/project/stream-1-quantum-biosensing/Wed, 01 Jan 2025 00:00:00 +0000https://quantomics.netlify.app/project/stream-1-quantum-biosensing/<h2 id="overview">Overview</h2> <p>Stream 1 is the hardware engine of the QuantOmics pipeline. Trainees in this stream design and fabricate next-generation quantum biosensor probes that achieve detection sensitivity at the <strong>attomolar level</strong> — capturing the decisive molecular events that trigger biological cascades long before conventional sensors can detect them.</p> <p>The core insight: biological systems exhibit immense signal amplification, where just a few molecules can trigger a cascade of events. Stream 1 builds the measurement tools that can capture these initial molecular events. This enables the entire downstream pipeline — genomic analysis and AI-guided therapeutic design — to operate on signals of unprecedented clarity.</p> <hr> <h2 id="research-focus-areas">Research Focus Areas</h2> <h3 id="nitrogen-vacancy-nv-center-diamond-probes">Nitrogen-Vacancy (NV) Center Diamond Probes</h3> <p>NV centers in diamond are atomic-scale quantum sensors with extraordinary sensitivity to magnetic fields, temperature, and single molecules. Trainees work on:</p> <ul> <li>Fabrication and functionalization of NV-center diamond nanoparticles for biological labeling</li> <li>Optically detected magnetic resonance (ODMR) signal readout</li> <li>Integration with microfluidic delivery systems for single-cell sensing</li> </ul> <h3 id="quantum-dot-synthesis--photonic-sensing">Quantum Dot Synthesis &amp; Photonic Sensing</h3> <p>Semiconductor quantum dots offer tunable optical properties for highly sensitive biosensing. Research projects include:</p> <ul> <li>Synthesis of biocompatible quantum dots (CdSe, InP, carbon-based) for specific molecular targeting</li> <li>Photonic crystal resonator integration for signal amplification</li> <li>Multiplexed detection platforms for simultaneous multi-analyte sensing</li> </ul> <h3 id="cmosmems-integrated-sensor-systems">CMOS/MEMS Integrated Sensor Systems</h3> <p>Miniaturized, integrated sensor platforms enable practical, deployable biosensors. Trainees engage in:</p> <ul> <li>Design of CMOS read-out circuitry for quantum sensor arrays</li> <li>MEMS-based microfluidic integration for sample handling</li> <li>Implantable and injectable wireless biosensor networks for real-time monitoring</li> <li>Energy-efficient signal conditioning electronics</li> </ul> <h3 id="spin-based-magnetometry">Spin-Based Magnetometry</h3> <p>Ultra-sensitive detection of magnetic signatures from biological processes:</p> <ul> <li>Spin-based detection of neurotransmitters and cellular signaling molecules</li> <li>Quantum-enhanced noise-limited detection strategies</li> <li>Integration with organ-on-a-chip platforms for in vitro validation</li> </ul> <hr> <h2 id="validation-platform">Validation Platform</h2> <p>A cornerstone of Stream 1 methodology is the use of <strong>patient-derived organoid and organ-on-a-chip platforms</strong>. These physiologically relevant 3D microenvironments mimic human tissue far more accurately than traditional 2D cell cultures. Trainees validate their quantum sensors against these biological systems — in partnership with Stream 2 biologists — to confirm performance in contexts that predict human clinical response.</p> <p>Partner organizations <strong>C2MI</strong> and <strong>Epiloid Biotech</strong> provide access to quantum fabrication infrastructure and organoid setups that are otherwise inaccessible to most Canadian universities.</p> <hr> <h2 id="example-trainee-projects">Example Trainee Projects</h2> <ul> <li><strong>NV-center nanosensor for attomolar cytokine detection</strong> — fabricating and characterizing a diamond NV probe functionalized for IL-6 detection in organoid supernatant</li> <li><strong>Quantum dot multiplexed assay for cancer biomarkers</strong> — designing a photonic chip that simultaneously detects three circulating tumor DNA fragments</li> <li><strong>Integrated CMOS biosensor for real-time cardiotoxicity screening</strong> — miniaturized sensor array for monitoring cardiomyocyte electrical activity in organ-on-chip models</li> <li><strong>Wireless implantable quantum magnetometer</strong> — injectable sensor for continuous in vivo monitoring of immune cell activity</li> </ul> <hr> <h2 id="stream-1-co-leads">Stream 1 Co-Leads</h2> <ul> <li><strong>Dr. Virgilio Valente</strong> (TMU) — CMOS/MEMS integrated sensors, wireless biosensor networks</li> <li><strong>Dr. Shayan Rayan</strong> (USask) — Quantum nanotechnology, nanopore integration</li> <li><strong>Dr. Harry Ruda</strong> (UofT) — Photonic sensors, semiconductor nanomaterials (Stanley Meek Chair in Advanced Nanotechnology)</li> <li><strong>Dr. Sara Mahshid</strong> (McGill) — Microfluidics, lab-on-chip biosensing</li> <li><strong>Dr. Stefania Impellizzeri</strong> (TMU) — Quantum dot synthesis, nanomaterial chemistry (Jet Ice Research Chair)</li> </ul> <hr> <h2 id="courses-supporting-stream-1">Courses Supporting Stream 1</h2> <ul> <li><strong>Course 1.1</strong> — Biosensor Engineering for Precision Health</li> <li><strong>Course 1.2</strong> — Quantum Nanotechnology for Life Sciences</li> <li><strong>Bootcamp 1.4</strong> — Multimodal-Omics Data Integration (connecting sensor output to genomic pipelines)</li> </ul>