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DNA-Based Biosensors for Environmental Monitoring Course

DNA-Based Biosensors for Environmental Monitoring Course

USD $59.00 USD $249.00Price range: USD $59.00 through USD $249.00

This program explores DNA-based biosensors for environmental monitoring, covering their design, development, and applications. Participants will learn to use biosensors to detect pollutants and pathogens.

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Aim

This course trains learners to design and understand DNA-based biosensors for environmental monitoring—using DNA as a highly specific recognition element to detect pollutants, pathogens, toxins, and heavy metals. Participants will learn the principles of DNA hybridization, aptamers, and DNA nanostructures; explore electrochemical, optical, and paper-based sensor formats; and understand sample-to-signal workflows for real-world matrices such as water, soil, and food. The program ends with a capstone where learners propose a complete DNA biosensor concept for a targeted environmental problem.

Program Objectives

  • Build Biosensor Foundations: Understand sensing basics—biorecognition, transduction, and signal processing.
  • DNA as a Recognition Tool: Learn hybridization probes, aptamers, and DNAzyme concepts for selective detection.
  • Sensor Platforms: Explore electrochemical, optical, fluorescence, colorimetric, and paper-based formats.
  • Environmental Sampling: Learn sample prep concepts for water/soil matrices and avoiding false signals.
  • Performance & Validation: Understand sensitivity, selectivity, LOD, calibration, and field validation workflows.
  • Deployment Thinking: Learn how sensors are packaged for field use, stability, and on-site interpretation.
  • Hands-on Outcome: Design a DNA biosensor blueprint for an environmental monitoring application.

Program Structure

Module 1: Why DNA Biosensors for the Environment?

  • Environmental monitoring needs: fast detection, portability, and low-cost sensing.
  • DNA strengths: programmability, specificity, and easy chemical modification.
  • Targets overview: pathogens, toxins, heavy metals, pesticides, antibiotics, microplastics-associated contaminants (overview).
  • Lab vs field: why real samples create real challenges.

Module 2: Biosensor Fundamentals (Recognition → Signal)

  • Core biosensor architecture: bioreceptor, transducer, readout, calibration.
  • Key metrics: sensitivity, selectivity, LOD/LOQ, dynamic range, response time.
  • Interference and matrix effects: why clean water and river water behave differently.
  • Control design: blanks, negative/positive controls, and replicates.

Module 3: DNA Hybridization Sensors (Probe Design Basics)

  • Hybridization principle: complementary binding and specificity logic.
  • Probe design thinking: length, GC content, secondary structure, mismatch discrimination.
  • Immobilization strategies: thiol-Au, biotin-streptavidin, surface chemistry overview.
  • Applications: microbial detection, genetic markers, and environmental DNA (eDNA) sensing.

Module 4: Aptamers and DNAzymes for Chemical Targets

  • Aptamers: DNA/RNA binders for small molecules and proteins (concept).
  • DNAzyme sensors: catalytic DNA for metal ions and toxins (concept).
  • Signal mechanisms: structure-switching, target-induced folding, competitive binding.
  • Use cases: lead/mercury detection, pesticide sensing, toxin monitoring (overview).

Module 5: Transduction Platforms (Electrochemical, Optical, Colorimetric)

  • Electrochemical DNA sensors: impedance/voltammetry concepts and why they’re field-friendly.
  • Optical sensors: fluorescence, FRET, SPR overview and interpretation discipline.
  • Colorimetric assays: nanoparticle-based readouts and paper-strip formats.
  • Choosing a platform: cost, portability, sensitivity, and target concentration range.

Module 6: Nanomaterials for Sensitivity Enhancement

  • Why nanomaterials help: surface area, conductivity, and signal amplification.
  • Common materials: AuNPs, graphene, CNTs, metal oxides (overview).
  • Functionalization basics: attaching DNA reliably and reproducibly.
  • Stability and reproducibility: avoiding “great results once” problems.

Module 7: Environmental Sample Handling & Avoiding False Results

  • Sample types: drinking water, wastewater, river water, soil extracts (what changes).
  • Pre-treatment overview: filtration, concentration, extraction, and inhibitor removal.
  • Matrix interference: humic substances, salts, biofouling and mitigation strategies.
  • Validation approach: spike-recovery, dilution linearity, and field comparison basics.

Module 8: Calibration, Data Interpretation & Sensor Validation

  • Calibration curves: standards, replicates, and reporting confidence.
  • Limit of detection vs practical detection: what’s “useful” for monitoring.
  • Repeatability and reproducibility: intra-day vs inter-day performance.
  • Field validation planning: comparing against reference lab methods (overview).

Module 9: Sensor Packaging, Field Deployment & IoT Integration (Overview)

  • Packaging for real use: cartridges, strips, and portable electrochemical readers.
  • Shelf-life and storage: keeping DNA and reagents stable.
  • Smart monitoring concept: mobile readouts, IoT dashboards, and geo-tagging.
  • Deployment constraints: user training, maintenance, and cost considerations.

Final Project

  • Create a DNA Biosensor Blueprint for an environmental monitoring target.
  • Include: target selection, DNA recognition strategy (probe/aptamer/DNAzyme), sensor platform choice, nanomaterial (optional), sample workflow, calibration plan, and validation approach.
  • Example projects: lead detection in groundwater, pathogen detection in wastewater, pesticide monitoring in irrigation water, toxin detection in food/water interface, eDNA-based biodiversity monitoring concept.

Participant Eligibility

  • UG/PG/PhD students in Biotechnology, Environmental Science, Chemistry, Nanotechnology, or related fields
  • Researchers working on biosensors, diagnostics, water quality, and environmental monitoring
  • Industry professionals in water treatment, environmental testing, and lab analytics
  • Basic understanding of DNA and lab methods is helpful (beginner-friendly structure included)

Program Outcomes

  • Core Understanding: Know how DNA biosensors work from recognition to signal output.
  • Design Skill: Ability to choose DNA strategy and transduction platform for a real target.
  • Validation Mindset: Understand calibration, matrix effects, and field validation planning.
  • Deployment Thinking: Understand packaging, stability, and field usability needs.
  • Portfolio Deliverable: A DNA biosensor blueprint you can showcase.

Program Deliverables

  • Access to e-LMS: Full access to course content, design templates, and reference resources.
  • Design Toolkit: probe/aptamer checklist, platform selection guide, calibration + validation template.
  • Case Exercises: interference troubleshooting, sensor selection scenarios, validation planning tasks.
  • Project Guidance: Mentor support for final blueprint development.
  • Final Assessment: Certification after assignments + capstone submission.
  • e-Certification and e-Marksheet: Digital credentials provided upon successful completion.

Future Career Prospects

  • Biosensor Research Intern / Associate
  • Environmental Diagnostics / Water Quality Analyst (Biosensing track)
  • Nanobiosensor Development Associate
  • R&D Associate (Environmental Monitoring Technologies)
  • IoT-Enabled Sensing Product Associate (Entry-level)

Job Opportunities

  • Environmental Testing Labs: Water quality and contamination monitoring teams.
  • Water & Wastewater Companies: Sensor-based monitoring and compliance analytics roles.
  • Biotech & Diagnostics Firms: Biosensor R&D and assay development teams.
  • Research Institutes: Environmental biotechnology, biosensing, and nanotechnology labs.
  • Smart City & IoT Companies: Environmental sensing platforms and deployment operations.
Category

E-LMS, E-LMS+Videos, E-LMS+Videos+Live

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