Program Structure

Module 1: Diagnostics Today—What’s Missing and Why Nano Helps

• Why conventional diagnostics can be slow, expensive, or lab-dependent.
• Point-of-care vs central lab testing: where biosensors shine.
• How nanotechnology changes the game: sensitivity, miniaturization, portability.
• Real-world diagnostic examples: infectious disease, cancer markers, metabolic tests (concept-level).

Module 2: Biosensors 101 (Simple and Solid Foundations)

• Core components: bioreceptor + transducer + signal readout.
• Biorecognition options: antibodies, enzymes, aptamers, DNA/RNA probes, cells.
• Common challenges: non-specific binding, cross-reactivity, drift, and sample complexity.
• How to think like a sensor designer: target → interface → signal → validation.

Module 3: Nanomaterials Toolkit for Biosensing

• Nanoparticles (AuNPs, magnetic NPs): signal amplification and target capture.
• Carbon nanomaterials (graphene, CNTs): conductivity and surface functionalization.
• Quantum dots and nanophotonics: bright optical readouts and multiplexing concepts.
• Nanostructured surfaces: improving immobilization and sensitivity.
• Choosing the right nanomaterial: stability, cost, scale-up, and safety thinking.

Module 4: Electrochemical Nano-Biosensors (Most Practical Category)

• Why electrochemical sensors are popular: cost-effective, portable, sensitive.
• Key readouts: amperometric, potentiometric, impedimetric (high-level).
• Nano-enhanced electrodes: boosting electron transfer and reducing noise.
• Interference handling: fouling, selectivity strategies, and signal stabilization.

Module 5: Optical Nano-Biosensors (Fast and Powerful Readouts)

• Colorimetric assays with nanoparticles: quick visual detection.
• Fluorescence/quantum dot sensing: sensitivity and multiplexing concepts.
• Plasmonics basics: SPR/LSPR intuition and why gold nanostructures matter.
• Trade-offs: instrumentation needs vs sensitivity and readout simplicity.

Module 6: Microfluidics, Lab-on-a-Chip, and Paper-Based Diagnostics

• Microfluidics fundamentals: controlling small volumes for faster reactions.
• Integrating nano-biosensors into chips for compact testing.
• Paper-based devices: affordable diagnostics for low-resource settings.
• Sample prep challenges: separation, filtration, concentration (high-level).

Module 7: Wearable and Continuous Monitoring Diagnostics

• Why continuous monitoring matters: early detection and personalized tracking.
• Wearable sensor targets: sweat biomarkers, glucose alternatives, inflammation markers (concept-level).
• Flexible substrates + nanomaterials: maintaining signal while bending/stretching.
• Data pipeline: calibration, drift correction, and user-friendly reporting.

Module 8: Designing for Real Samples (Where Most Sensors Fail)

• Understanding matrix effects: blood, saliva, urine, food, and environmental samples.
• Specificity strategies: blocking, surface chemistry, and smart assay design.
• Calibration and controls: positive/negative controls, standard curves, repeatability.
• Robustness thinking: temperature, storage stability, shelf-life and packaging.

Module 9: Validation, Translation, and Industry Readiness

• Key performance terms: LoD, LoQ, sensitivity, specificity, accuracy, precision.
• Prototyping to product: scaling, reproducibility, and manufacturing constraints.
• Regulatory mindset (high-level): documentation, quality, risk management.
• Ethics and data privacy for diagnostics and connected devices.

Final Project

• Create a Nano-Biosensor Design Brief for an enhanced diagnostic application.
• Include: target biomarker, biorecognition element, nanomaterial choice, sensor format, assay workflow, validation plan, and deployment scenario.
• Example themes: “rapid pathogen test,” “cancer marker screening,” “water contamination biosensor,” or “wearable inflammation monitor.”