Bruce Y Lee1, Patrick T Wedlock2, Leila A Haidari3, Kate Elder4, Julien Potet4, Rachel Manring5, Diana L Connor2, Marie L Spiker2, Kimberly Bonner6, Arjun Rangarajan4, Delphine Hunyh4, Shawn T Brown3. 1. HERMES Logistics Modeling Team, Baltimore, MD and Pittsburgh, PA, United States; Global Obesity Prevention Center (GOPC) at Johns Hopkins University, Johns Hopkins Bloomberg School of Public Health, Baltimore, MD, United States. Electronic address: brucelee@jhu.edu. 2. HERMES Logistics Modeling Team, Baltimore, MD and Pittsburgh, PA, United States; Global Obesity Prevention Center (GOPC) at Johns Hopkins University, Johns Hopkins Bloomberg School of Public Health, Baltimore, MD, United States. 3. HERMES Logistics Modeling Team, Baltimore, MD and Pittsburgh, PA, United States; Global Obesity Prevention Center (GOPC) at Johns Hopkins University, Johns Hopkins Bloomberg School of Public Health, Baltimore, MD, United States; Pittsburgh Supercomputing Center (PSC), Carnegie Mellon University, Pittsburgh, PA, United States. 4. Médecins Sans Frontières, Geneva, Switzerland; Médecins Sans Frontières, New York City, NY, United States. 5. Department of Epidemiology, Mailman School of Public Health at Columbia University, New York City, NY, United States. 6. University of Minnesota, St. Paul/Minneapolis, MN, United States.
Abstract
BACKGROUND: While our previous work has shown that replacing existing vaccines with thermostable vaccines can relieve bottlenecks in vaccine supply chains and thus increase vaccine availability, the question remains whether this benefit would outweigh the additional cost of thermostable formulations. METHODS: Using HERMES simulation models of the vaccine supply chains for the Republic of Benin, the state of Bihar (India), and Niger, we simulated replacing different existing vaccines with thermostable formulations and determined the resulting clinical and economic impact. Costs measured included the costs of vaccines, logistics, and disease outcomes averted. RESULTS: Replacing a particular vaccine with a thermostable version yielded cost savings in many cases even when charging a price premium (two or three times the current vaccine price). For example, replacing the current pentavalent vaccine with a thermostable version without increasing the vaccine price saved from $366 to $10,945 per 100 members of the vaccine's target population. Doubling the vaccine price still resulted in cost savings that ranged from $300 to $10,706, and tripling the vaccine price resulted in cost savings from $234 to $10,468. As another example, a thermostable rotavirus vaccine (RV) at its current (year) price saved between $131 and $1065. Doubling and tripling the thermostable rotavirus price resulted in cost savings ranging from $102 to $936 and $73 to $808, respectively. Switching to thermostable formulations was highly cost-effective or cost-effective in most scenarios explored. CONCLUSION: Medical cost and productivity savings could outweigh even significant price premiums charged for thermostable formulations of vaccines, providing support for their use.
BACKGROUND: While our previous work has shown that replacing existing vaccines with thermostable vaccines can relieve bottlenecks in vaccine supply chains and thus increase vaccine availability, the question remains whether this benefit would outweigh the additional cost of thermostable formulations. METHODS: Using HERMES simulation models of the vaccine supply chains for the Republic of Benin, the state of Bihar (India), and Niger, we simulated replacing different existing vaccines with thermostable formulations and determined the resulting clinical and economic impact. Costs measured included the costs of vaccines, logistics, and disease outcomes averted. RESULTS: Replacing a particular vaccine with a thermostable version yielded cost savings in many cases even when charging a price premium (two or three times the current vaccine price). For example, replacing the current pentavalent vaccine with a thermostable version without increasing the vaccine price saved from $366 to $10,945 per 100 members of the vaccine's target population. Doubling the vaccine price still resulted in cost savings that ranged from $300 to $10,706, and tripling the vaccine price resulted in cost savings from $234 to $10,468. As another example, a thermostable rotavirus vaccine (RV) at its current (year) price saved between $131 and $1065. Doubling and tripling the thermostable rotavirus price resulted in cost savings ranging from $102 to $936 and $73 to $808, respectively. Switching to thermostable formulations was highly cost-effective or cost-effective in most scenarios explored. CONCLUSION: Medical cost and productivity savings could outweigh even significant price premiums charged for thermostable formulations of vaccines, providing support for their use.
Authors: Bruce Y Lee; Benjamin Schreiber; Angela R Wateska; Diana L Connor; Hamadou M Dicko; Philippe Jaillard; Mercy Mvundura; Carol Levin; Mélanie Avella; Leila A Haidari; Shawn T Brown Journal: Vaccine Date: 2015-04-18 Impact factor: 3.641
Authors: Christopher L Karp; Deborah Lans; José Esparza; Eleanore B Edson; Katey E Owen; Christopher B Wilson; Penny M Heaton; Orin S Levine; Raja Rao Journal: Vaccine Date: 2015-06-06 Impact factor: 3.641
Authors: Shawn T Brown; Benjamin Schreiber; Brigid E Cakouros; Angela R Wateska; Hamadou M Dicko; Diana L Connor; Philippe Jaillard; Mercy Mvundura; Bryan A Norman; Carol Levin; Jayant Rajgopal; Mélanie Avella; Caroline Lebrun; Erin Claypool; Proma Paul; Bruce Y Lee Journal: Vaccine Date: 2014-05-09 Impact factor: 3.641
Authors: Bruce Y Lee; Leila A Haidari; Wendy Prosser; Diana L Connor; Ruth Bechtel; Amelia Dipuve; Hidayat Kassim; Balbina Khanlawia; Shawn T Brown Journal: Vaccine Date: 2016-08-26 Impact factor: 3.641
Authors: Jotam G Pasipanodya; Scott Jn McNabb; Peter Hilsenrath; Sejong Bae; Kristine Lykens; Edgar Vecino; Guadalupe Munguia; Thaddeus L Miller; Gerry Drewyer; Stephen E Weis Journal: BMC Public Health Date: 2010-05-19 Impact factor: 3.295
Authors: Richard D Rheingans; Lynn Antil; Robert Dreibelbis; Laura Jean Podewils; Joseph S Bresee; Umesh D Parashar Journal: J Infect Dis Date: 2009-11-01 Impact factor: 5.226
Authors: Tina-Marie Assi; Shawn T Brown; Ali Djibo; Bryan A Norman; Jayant Rajgopal; Joel S Welling; Sheng-I Chen; Rachel R Bailey; Souleymane Kone; Hailu Kenea; Diana L Connor; Angela R Wateska; Anirban Jana; Stephen R Wisniewski; Willem G Van Panhuis; Donald S Burke; Bruce Y Lee Journal: BMC Public Health Date: 2011-06-02 Impact factor: 3.295
Authors: Mario Amacker; Charli Smardon; Laura Mason; Jack Sorrell; Kirk Jeffery; Michael Adler; Farien Bhoelan; Olga Belova; Mark Spengler; Beena Punnamoottil; Markus Schwaller; Olivia Bonduelle; Behazine Combadière; Toon Stegmann; Andrew Naylor; Richard Johnson; Desmond Wong; Sylvain Fleury Journal: NPJ Vaccines Date: 2020-05-18 Impact factor: 7.344
Authors: Sarah N Cox; Patrick T Wedlock; Sarah W Pallas; Elizabeth A Mitgang; Tatenda T Yemeke; Sarah M Bartsch; Taiwo Abimbola; Sheryl S Sigemund; Aaron Wallace; Sachiko Ozawa; Bruce Y Lee Journal: Vaccine Date: 2021-05-25 Impact factor: 3.641
Authors: Danielle A Wagner-Muñiz; Shannon L Haughney; Sean M Kelly; Michael J Wannemuehler; Balaji Narasimhan Journal: Front Immunol Date: 2018-03-02 Impact factor: 7.561
Authors: Natalie Carvalho; Mohammad Enamul Hoque; Victoria L Oliver; Abbey Byrne; Michelle Kermode; Pete Lambert; Michelle P McIntosh; Alison Morgan Journal: BMC Med Date: 2020-07-28 Impact factor: 8.775
Authors: Mario Amacker; Charli Smardon; Laura Mason; Jack Sorrell; Kirk Jeffery; Michael Adler; Farien Bhoelan; Olga Belova; Mark Spengler; Beena Punnamoottil; Markus Schwaller; Olivia Bonduelle; Behazine Combadière; Toon Stegmann; Andrew Naylor; Richard Johnson; Desmond Wong; Sylvain Fleury Journal: NPJ Vaccines Date: 2020-05-18 Impact factor: 7.344
Authors: Patrick T Wedlock; Elizabeth A Mitgang; Sheryl S Siegmund; Jay DePasse; Jennifer Bakal; Jim Leonard; Joel Welling; Shawn T Brown; Bruce Y Lee Journal: Vaccine Date: 2018-08-23 Impact factor: 3.641
Authors: Harrison J Esterly; Candice J Crilly; Samantha Piszkiewicz; Dane J Shovlin; Gary J Pielak; Brooke E Christian Journal: Front Pharmacol Date: 2020-10-07 Impact factor: 5.810