Online/ e-LMS
Self Paced
Moderate
1 Month
About
Lab-on-a-Chip (LOC) technology represents a significant leap in miniaturizing biological processes, offering enhanced precision, speed, and cost-efficiency. This program delves into the world of LOC, emphasizing its applications in genetic engineering and molecular diagnostics. Participants will learn how these devices integrate complex laboratory functions into a single chip, revolutionizing fields like genomics, proteomics, and personalized medicine. Through a combination of theoretical knowledge and practical case studies, the course covers the entire workflow of developing and using LOC systems for genetic manipulation and diagnostic purposes.
In addition to core engineering concepts, participants will explore various fabrication techniques and the role of microfluidics in LOC devices. The program will emphasize how these technologies are employed to accelerate genetic experiments, reduce reagent use, and enable point-of-care diagnostics. With the growing importance of precision medicine, LOC technology is becoming indispensable in genetic research and healthcare innovation.
Aim
This program aims to introduce participants to Lab-on-a-Chip (LOC) technology, focusing on its applications in miniaturized genetic engineering. The course will explore the design, fabrication, and implementation of LOC devices, enabling participants to understand their role in advancing genetic engineering, diagnostics, and molecular biology research.
Program Objectives
- Understand the fundamental concepts of Lab-on-a-Chip technology.
- Explore the applications of LOC in miniaturized genetic engineering and diagnostics.
- Learn fabrication techniques and microfluidic principles involved in LOC devices.
- Analyze case studies of LOC applications in biotechnology and healthcare.
- Evaluate the future trends and innovations in LOC technology for genetic manipulation.
Program Structure
Week 1: Introduction to Lab-on-a-Chip Technology
- Overview of Lab-on-a-Chip: Understanding the fundamentals and history.
- Miniaturized Laboratories: Benefits and challenges of LOC technology.
- Microfluidics and LOC: Understanding the integration of microfluidics in genetic engineering.
- Designing LOC Devices: Key principles and considerations for LOC development.
Week 2: Applications in Genetic Engineering
- LOC in Genetic Manipulation: Case studies of LOC applications in gene editing and expression.
- Molecular Diagnostics Using LOC: Innovations in disease diagnostics and genetic testing.
- LOC for Point-of-Care Testing: Revolutionizing healthcare with portable genetic analysis tools.
- Ethical and Regulatory Considerations in LOC Technologies: Navigating legal and ethical implications.
Week 3: Fabrication and BioMEMS
- Microfabrication Techniques: Methods for creating microfluidic and LOC devices.
- BioMEMS: Integrating biosensors and MEMS with LOC systems.
- Materials and Design: Choosing appropriate materials and optimizing LOC performance.
- Hands-on Case Study: Reviewing successful applications of LOC in the industry.
Week 4: Future Trends and Innovations
- Advances in LOC Technology: Exploring new developments and innovations.
- LOC and Precision Medicine: Personalized healthcare using LOC devices.
- The Future of Genetic Engineering with LOC: Emerging technologies and applications.
- Careers in LOC and Biomedical Engineering: Preparing for the job market.
Participant’s Eligibility
- Undergraduate degree in Molecular Biology, Bioengineering, Biomedical Engineering, or related fields.
- Professionals in biotechnology or medical diagnostics industries.
- Individuals with a keen interest in miniaturized technology and genetic engineering.
Program Outcomes
- Mastery of LOC technology and its applications in genetic engineering.
- Practical understanding of microfluidic systems and device fabrication.
- Ability to design and implement LOC devices for diagnostics and research.
- Insights into the future of LOC technology in healthcare and biotechnology.
- Knowledge of case studies showcasing successful LOC applications.
Fee Structure
Standard Fee: INR 4,998 USD 110
Discounted Fee: INR 2499 USD 55
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Key Takeaways
Program Deliverables
- Access to e-LMS
- Real Time Project for Dissertation
- Project Guidance
- Paper Publication Opportunity
- Self Assessment
- Final Examination
- e-Certification
- e-Marksheet
Future Career Prospects
- Biomedical Device Engineer
- Genetic Engineering Researcher
- Microfluidics Specialist
- Molecular Diagnostics Developer
- Biochip Design Engineer
- Point-of-Care Technology Developer
Job Opportunities
- Research Scientist in microfluidics and biomedical applications.
- Biomedical Engineer in medical device companies.
- Genetic Engineering Expert in biotechnological firms.
- Diagnostics Technology Specialist developing portable health solutions.
- Quality Assurance Engineer in microchip fabrication and diagnostics tools.
- R&D Engineer in biosensor and biochip development.
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Good and Very Informative and learnt new things
Thank you