Blood transfusion for deep space exploration

• Published in: Transfusion (Philadelphia, Pa.) Vol. 59; no. 10; pp. 3077 - 3083
• Main Authors: Nowak, Elizabeth S., Reyes, David P., Bryant, Barbara J., Cap, Andrew P., Kerstman, Eric L., Antonsen, Erik L.
• Format: Journal Article
• Language: English
• Published: Hoboken, USA John Wiley & Sons, Inc 01.10.2019; Wiley Subscription Services, Inc
• Subjects: Astronauts; Blood banks; Blood transfusion; Blood transfusions; Deep space; Exploration; Health risks; Hemoglobin; Hemorrhage; Literature reviews; Microgravity; Resuscitation; Space exploration; Space flight; Space missions; Terrestrial environments; Transfusion
• ISSN: 0041-1132; 1537-2995
• DOI: 10.1111/trf.15493

BACKGROUND Astronauts on exploration missions may be at risk for traumatic injury and medical conditions that lead to life threatening hemorrhage. Resuscitation protocols are limited by the austere conditions of spaceflight. Solutions may be found in low‐resource terrestrial settings. The existing literature on alternative blood product administration and walking blood banks was evaluated for applicability to spaceflight. STUDY DESIGN AND METHODS A literature review was done using PubMed and Google Scholar. References were crosschecked for additional publications not identified using the initial search terms. Twenty‐seven articles were identified, including three controlled trials, six retrospective cohort analyses, 15 reviews, one case report, and two experimental studies. RESULTS Solutions to blood transfusion in austere settings include lyophilized blood products, hemoglobin‐based oxygen carriers (HBOCs), and fresh whole blood. Many of these products are investigational. Protocols for walking blood banks include methods for screening and activating donors, transfusion, and monitoring for adverse reactions. Microgravity and mission limitations create additional challenges for transfusion, including baseline physiologic changes, difficulty reconstituting lyophilized products, risk of air emboli during transfusion, equipment constraints, and limited evacuation and surgical options. CONCLUSION Medical planning for space exploration should consider the possibility of acute blood loss. A model for “floating” blood banks based on terrestrial walking blood bank protocols from austere environments is presented, with suggestions for future development. Constraints on volume, mass, storage, and crew, present challenges to blood transfusion in space and must be weighed against the benefits of expanding medical capabilities.