The pharmacy curriculum at North East Adventist University West Jaintia Hills is meticulously structured to provide students with a balanced blend of theoretical knowledge and practical skills. The program spans eight semesters, each designed to build upon the previous one, ensuring progressive learning and specialization.
Course Structure Overview
| Semester | Course Code | Course Title | Credit Structure (L-T-P-C) | Prerequisites |
|---|---|---|---|---|
| 1 | PHY101 | Basic Organic Chemistry | 3-0-0-3 | None |
| 1 | BIO101 | Introduction to Biochemistry | 3-0-0-3 | None |
| 1 | MAT101 | Mathematics I | 3-0-0-3 | None |
| 1 | PHS101 | Physics for Pharmacy | 3-0-0-3 | None |
| 1 | CHM101 | Chemistry Lab | 0-0-3-1 | None |
| 2 | PHY201 | Physical Pharmacy | 3-0-0-3 | PHY101 |
| 2 | BIO201 | Molecular Biology | 3-0-0-3 | BIO101 |
| 2 | MAT201 | Mathematics II | 3-0-0-3 | MAT101 |
| 2 | PHS201 | Quantum Physics and Spectroscopy | 3-0-0-3 | PHS101 |
| 2 | CHM201 | Chemistry Lab II | 0-0-3-1 | CHM101 |
| 3 | PHR301 | Pharmacology I | 3-0-0-3 | BIO201 |
| 3 | MED301 | Medicinal Chemistry | 3-0-0-3 | PHY201 |
| 3 | PHR302 | Pharmaceutics I | 3-0-0-3 | PHY201 |
| 3 | BIO301 | Biophysics and Pharmacodynamics | 3-0-0-3 | BIO201 |
| 3 | CHM301 | Organic Chemistry Lab | 0-0-3-1 | CHM101 |
| 4 | PHR401 | Clinical Pharmacology | 3-0-0-3 | PHR301 |
| 4 | PHR402 | Pharmaceutical Analysis | 3-0-0-3 | PHR302 |
| 4 | PHR403 | Drug Design and Development | 3-0-0-3 | MED301 |
| 4 | BIO401 | Genetics and Genomics | 3-0-0-3 | BIO201 |
| 4 | CHM401 | Advanced Organic Chemistry Lab | 0-0-3-1 | CHM301 |
| 5 | PHR501 | Pharmacognosy and Natural Product Chemistry | 3-0-0-3 | PHR301 |
| 5 | PHR502 | Pharmaceutical Microbiology | 3-0-0-3 | BIO201 |
| 5 | PHR503 | Pharmaceutical Technology | 3-0-0-3 | PHR402 |
| 5 | BIO501 | Immunology and Immunopharmacology | 3-0-0-3 | BIO401 |
| 5 | CHM501 | Pharmaceutical Chemistry Lab | 0-0-3-1 | CHM401 |
| 6 | PHR601 | Pharmaceutical Quality Assurance | 3-0-0-3 | PHR503 |
| 6 | PHR602 | Regulatory Affairs in Pharmacy | 3-0-0-3 | PHR501 |
| 6 | PHR603 | Pharmaceutical Economics and Management | 3-0-0-3 | PHR402 |
| 6 | BIO601 | Toxicology and Environmental Health | 3-0-0-3 | BIO501 |
| 6 | CHM601 | Research Methods in Pharmacy | 0-0-3-1 | None |
| 7 | PHR701 | Advanced Clinical Practice | 3-0-0-3 | PHR401 |
| 7 | PHR702 | Drug Development and Formulation | 3-0-0-3 | PHR503 |
| 7 | PHR703 | Pharmaceutical Research Project | 0-0-6-2 | CHM601 |
| 7 | BIO701 | Biotechnology Applications in Pharmacy | 3-0-0-3 | BIO601 |
| 7 | CHM701 | Capstone Project Lab | 0-0-6-2 | PHR702 |
| 8 | PHR801 | Final Year Thesis/Project | 0-0-12-4 | PHR703 |
| 8 | PHR802 | Industry Internship | 0-0-6-2 | PHR703 |
| 8 | PHR803 | Professional Ethics in Pharmacy | 3-0-0-3 | None |
| 8 | BIO801 | Emerging Trends in Pharmacology | 3-0-0-3 | BIO701 |
| 8 | CHM801 | Pharmaceutical Innovations Lab | 0-0-6-2 | CHM701 |
Advanced Departmental Elective Courses
Computational Drug Design: This course introduces students to molecular modeling and simulation techniques used in drug discovery. Students learn how to predict protein structures, design novel compounds, and evaluate binding affinities using software tools like AutoDock, MOE, and Schrodinger.
Nanostructured Drug Delivery Systems: Focused on nanotechnology applications in pharmacy, this course explores the development of nanoparticles, liposomes, and micelles for targeted drug delivery. Students gain hands-on experience with advanced characterization techniques such as dynamic light scattering (DLS) and transmission electron microscopy (TEM).
Pharmacogenomics: This elective delves into the intersection of genetics and pharmacology, examining how genetic variations affect drug metabolism and response. Students analyze real-world datasets to identify genetic markers associated with drug efficacy and adverse reactions.
Drug Metabolism and Pharmacokinetics: A detailed study of how drugs are absorbed, distributed, metabolized, and eliminated in the body. The course includes both theoretical and practical components covering enzyme kinetics, bioavailability studies, and clinical applications.
Pharmaceutical Quality Control: This course covers regulatory standards and quality assurance practices in pharmaceutical manufacturing. Students learn about Good Manufacturing Practices (GMP), analytical validation, and risk assessment methodologies used in the industry.
Regulatory Affairs in Drug Development: Designed for students interested in working in regulatory affairs, this course provides an overview of FDA, EMA, and other global regulatory frameworks. Topics include preclinical studies, clinical trial design, and post-market surveillance strategies.
Pharmaceutical Economics and Outcomes Research: This course examines the economic aspects of drug development and use, including cost-effectiveness analysis, budget impact modeling, and health technology assessment (HTA). Students engage in case studies involving real-world healthcare systems.
Advanced Clinical Pharmacotherapy: Focused on applying pharmacological principles to clinical practice, this course covers disease-specific treatment protocols, drug interactions, and personalized medicine approaches. Students participate in simulated patient scenarios to enhance decision-making skills.
Pharmaceutical Biotechnology: Explores the application of biotechnological methods in pharmaceutical research and development. Topics include recombinant DNA technology, monoclonal antibodies, gene therapy, and biosimilar development.
Global Health and Drug Policy: This course addresses global challenges in drug access, affordability, and public health policy. Students examine international initiatives such as the WHO Essential Medicines List, TRIPS agreement, and drug pricing strategies across different countries.
Project-Based Learning Philosophy
The department's philosophy on project-based learning is centered around experiential education that bridges theory and practice. Projects are designed to simulate real-world challenges in pharmaceutical sciences, encouraging students to think critically and innovate.
Mini-Projects: Throughout the program, students engage in mini-projects that typically last 2-3 months. These projects begin in the third year and involve small teams of 4-5 students working under faculty supervision. Projects often focus on specific research questions related to drug discovery, formulation development, or clinical applications.
Final-Year Thesis/Capstone Project: In the final two semesters, students undertake a comprehensive capstone project that integrates all aspects of their learning. The thesis is typically 100-150 pages long and includes literature review, methodology, data analysis, and conclusions. Students present their findings to a panel of faculty members and industry experts.
The selection process for projects involves a proposal submission phase where students identify research areas aligned with faculty expertise. Faculty mentors are assigned based on project relevance, student interest, and available resources. Evaluation criteria include scientific rigor, innovation, presentation quality, and impact potential.