BIOE 124 (BIOE 224) - Basic Principles of Drug Delivery (3 Units)
Course Overview
Summary
(From Syllabus) BioE 124/224 “focuses on providing students with the foundations needed to understand contemporary literature in drug delivery”. Its goal is to “give students the ability to understand problems in drug delivery. Emphasis is placed on the design and synthesis of new molecules for drug delivery.” It has a mixture of undergraduate and graduate students.
Literature-focused lectures, homework, and exams covering a wide range of drug delivery topics.
Prerequisites
CHEM 3A and MCB C100A
BIOE 11 or CHEM 3B; BIOE 103; and BIOE 104
Topics Covered
- Introduction, pKa, hydrolysis reactions and acid/base catalysis
- Elimination and fragmentation reactions, self-immolative linkers and design of prodrugs
- The HepDirect family of prodrugs
- The strategies for developing “traceless” linkers
- Disulfide bonds, other thiol-specific reactions, antibody drug conjugates and polymer drug conjugates based on free radical polymerization
- PEG Drug Conjugates
- Block Copolymer Micelles for Drug Delivery
- Polymers for Controlled Release
- Hydrogels
- Endosomal Disruption
- RAFT Polymerization
- Introduction to Immunology and Immunoengineering
- Including the design and synthesis of vaccine delivery vehicles
- TLR Signaling and Immuno-Engineering
- Drug delivery to the brain and oral drug delivery
- siRNA delivery and the delivery of nucleic acid therapeutics
- Intracellular protein delivery and peptide delivery
- Peptide Therapeutics and Delivery
- Applications of drug delivery in the treatment of cancer
- Tumor Biology and Drug Delivery to Tumors
- Tumor Drug Delivery with Nanoparticles and cells
- Applications of drug delivery in the treatment of atherosclerosis
- Atherosclerosis and Heart Failure
- Drug Delivery to the Heart Examples
- Applications of drug delivery in the treatment of infectious diseases
- Bacterial Drug resistance, and Antibiotic Drug Delivery
- Emerging therapeutic strategies
- Genome Editing and CRISPR/Cas9
- Elastin and Protein Conjugations
- Angiogenesis and Biomaterials
Workload
Coursework
- Homework
- ~6 in total
- Each one ~ 6 questions some with multiple parts
- Including but not limited to fundamental chemistry, literature reading, specific delivery design/mechanisms, specific biological system, design new molecules subject to certain drug delivery constraints and requirements.
- Two midterms and one final
Time Commitment
3 hours of lecture per week
Choosing the Course
When to take
Fall only.
This class fulfills the Chem/ChemBio allied subject requirement, as well as the ChemE engineering elective requirement
What Next?
- If the mathematical / transport side of the drug delivery is the main interest for the next step, BioE 104 – Biological Transport Phenomena would be a good fundamental.
- If the interest for the next step is a disease (i.e. cancer, or maybe immunology), corresponding MCB or biology courses might be more in depth.
- If the interest for the next step is more drug molecule synthesis, maybe courses such as the following should be considered:
Additional Comments and Tips
The blackboard notes during the lectures could be quite important.
Written by: Francesca-Zhoufan Li
Last edited: Fall 2018