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Capacity and Inventory Optimization for Pharmaceutical Industry
by
Huong Thi Dang
Bachelor of Business Administration, National University of Singapore, 2013
and
Brett Anthony Elgersma
Bachelor of Science, Iowa State University, 2016
SUBMITTED TO THE PROGRAM IN SUPPLY CHAIN MANAGEMENT
IN PARTIAL FULFILLMENT OF THE REQUIREMENTS FOR THE DEGREE OF
MASTER OF APPLIED SCIENCE IN SUPPLY CHAIN MANAGEMENT
AT THE
MASSACHUSETTS INSTITUTE OF TECHNOLOGY
May 2020
© 2020 Huong Thi Dang & Brett Anthony Elgersma. All rights reserved.
The authors hereby grant to MIT permission to reproduce and to distribute publicly paper and electronic
copies of this capstone document in whole or in part in any medium now known or hereafter created.
Signature of Author: ____________________________________________________________________
Department of Supply Chain Management
May 1, 2020
Signature of Author: ____________________________________________________________________
Department of Supply Chain Management
May 1, 2020
Certified by: __________________________________________________________________________
Dr. Nima Kazemi
Postdoctoral Associate, Center for Transportation and Logistics
Capstone Advisor
Accepted by: __________________________________________________________________________
Prof. Yossi Sheffi
Director, Center for Transportation and Logistics
Elisha Gray II Professor of Engineering Systems
Professor, Civil and Environmental Engineering
Capacity and Inventory Optimization for Pharmaceutical Industry
by
Huong Thi Dang
and
Brett Anthony Elgersma
Submitted to the Program in Supply Chain Management
on May 1, 2020 in Partial Fulfillment of the
Requirements for the Degree of Master of Applied Science in Supply Chain Management
ABSTRACT
The pharmaceutical industry is subject to many unique constraints, due in part to both product
characteristics and regulatory guidelines. Nevertheless, pharmaceutical companies are expected to be
able to serve customers that rely on their products, even as demand can be unpredictable and erratic.
Pharmaceutical companies have choices in how they deal with demand uncertainty, but two schools of
thought dominate: hold additional inventory or employ additional capacity. Finding the right balance
between additional inventory and excess capacity proves difficult given product shelf-life constraints and
long production ramp-up lead times. This study develops a mixed-integer linear program that optimizes
inventory policy and production capacity policy under stochastic demand scenarios at a single node of the
supply chain by minimizing inventory costs, production costs, and anticipated write-off costs. Scenarios of
demand uncertainty with different probabilities are simulated to provide insights into key drivers of the
model behavior and guide insights into useful inventory policies. Findings demonstrate that in an
environment characterized by long production ramp-up lead times and products constrained by shelf life,
neither additional inventory or excess production capacity alone is sufficient for hedging demand
uncertainty. Therefore, pharmaceutical companies should consider employing the two strategies together
to meet market demand with the optimal cost.
Capstone Advisor: Dr. Nima Kazemi
Title: Postdoctoral Associate, Center for Transportation and Logistics
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ACKNOWLEDGMENTS
We would like to thank Dr. Nima Kazemi for guiding us through this process, challenging us to think
differently, and pushing us to be the best versions of ourselves. Without his feedback and tutelage, we
would still be trying to figure out where to begin. A special thank you is also due to Mr. Nicholas Wigdahl
and the rest of the Supply Chain team at F. Hoffman-LaRoche Ltd. We appreciate your guidance through
the intricate workings of pharmaceutical supply chains. Finally, we would like to thank our families,
friends, and classmates for their patience, understanding, and support throughout this research process.
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TABLE OF CONTENTS
LIST OF FIGURES 5
LIST OF TABLES 5
1. INTRODUCTION 6
1.1. Motivation 6
1.2. Problem Statement 6
2. LITERATURE REVIEW 8
2.1. Inventory Holding Costs 8
2.2. Production Planning 9
2.3. Capacity Expansion 9
3. METHODOLOGY 12
3.1. Interview and Data Collection 13
3.2. Scope and Limitations 16
3.3. Assumptions 16
3.4. Mathematical Formulation 17
3.4.1. Notations 17
3.4.2. Objective Function 19
3.4.3. Constraints 21
4. RESULTS, ANALYSIS, AND DISCUSSION 22
4.1. Simulation Description 22
4.2. Simulation Parameters 23
4.3. Simulation Results 23
4.4. Model Parameter Sensitivity 24
4.4.1. Production Line Dedication 25
4.4.2. Forecast Error 26
4.4.3. Customer Service Target Level 27
4.5. Insights and Management Recommendations 28
5. CONCLUSION 29
REFERENCES 30
APPENDIX A 31
APPENDIX B 33
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