A field polymerizing hydrogel enables simultaneous antimicrobial, hemostatic, and analgesic delivery in traumatic wounds

Elizabeth A. Pumford; Christopher D. Hamad; Amaka I. Enueme; Zeinab Mamouei; Nicholas Peterson; Christopher Hart; Chad Ishmael; Alan Li; Rahul Sobti; Jack Pearce; Jeremiah Taylor; Micah Ralston; Jared D. Wainwright; Kan Nakamoto; Perenlei Enkhbaatar; Kaitlyn A. Cook; Kevin P. Francis; John Adams; Alexandra Stavrakis; Joseph C. Wenke; Andrea M. Kasko; Nicholas M. Bernthal

doi:10.1038/s41598-026-37521-y

A field polymerizing hydrogel enables simultaneous antimicrobial, hemostatic, and analgesic delivery in traumatic wounds

Elizabeth A. Pumford
, Christopher D. Hamad
, Amaka I. Enueme
, Zeinab Mamouei
, Nicholas Peterson
, Christopher Hart
, Chad Ishmael
, Alan Li
, Rahul Sobti
, Jack Pearce
, Jeremiah Taylor
, Micah Ralston
, Jared D. Wainwright
, Kan Nakamoto
, Perenlei Enkhbaatar
, Kaitlyn A. Cook
, Kevin P. Francis
, John Adams
, Alexandra Stavrakis
, Joseph C. Wenke

Andrea M. Kasko, Nicholas M. Bernthal

Research output: Contribution to journal › Article › peer-review

Abstract

Traumatic injuries in resource-limited settings, such as remote, rural, or disaster-affected environments, require wound care solutions that can effectively address hemorrhage, infection, and pain outside of traditional clinical infrastructure. We developed a field-polymerizable hydrogel wound dressing capable of delivering tranexamic acid (hemostatic), vancomycin and tobramycin (broad-spectrum antibiotics), and lidocaine (analgesic) directly to the site of injury. Using computational modeling, we designed a lightweight, rugged hydrogel that polymerizes rapidly with potable water and conforms to irregular wound beds. The system demonstrated burst release of hemostatic and analgesic agents and sustained antibiotic release over four days. In vitro and in vivo testing confirmed the hydrogel’s ability to stabilize clots, prevent fibrinolysis, and eradicate polymicrobial gram-positive and gram-negative bacterial infections in a murine model of open fracture. Large animal studies further validated its translational potential in a large, complex wound. This modular, multifunctional platform provides a field-ready solution for wound management in austere environments, with the potential to reduce infection, control bleeding, and improve wound stabilization when access to definitive care is delayed.

Original language	English (US)
Article number	6950
Journal	Scientific reports
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41598-026-37521-y
State	Published - Dec 2026

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Pumford, E. A., Hamad, C. D., Enueme, A. I., Mamouei, Z., Peterson, N., Hart, C., Ishmael, C., Li, A., Sobti, R., Pearce, J., Taylor, J., Ralston, M., Wainwright, J. D., Nakamoto, K., Enkhbaatar, P., Cook, K. A., Francis, K. P., Adams, J., Stavrakis, A., ... Bernthal, N. M. (2026). A field polymerizing hydrogel enables simultaneous antimicrobial, hemostatic, and analgesic delivery in traumatic wounds. Scientific reports, 16(1), Article 6950. https://doi.org/10.1038/s41598-026-37521-y

Pumford, EA, Hamad, CD, Enueme, AI, Mamouei, Z, Peterson, N, Hart, C, Ishmael, C, Li, A, Sobti, R, Pearce, J, Taylor, J, Ralston, M, Wainwright, JD, Nakamoto, K, Enkhbaatar, P, Cook, KA, Francis, KP, Adams, J, Stavrakis, A, Wenke, JC, Kasko, AM & Bernthal, NM 2026, 'A field polymerizing hydrogel enables simultaneous antimicrobial, hemostatic, and analgesic delivery in traumatic wounds', Scientific reports, vol. 16, no. 1, 6950. https://doi.org/10.1038/s41598-026-37521-y

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title = "A field polymerizing hydrogel enables simultaneous antimicrobial, hemostatic, and analgesic delivery in traumatic wounds",

abstract = "Traumatic injuries in resource-limited settings, such as remote, rural, or disaster-affected environments, require wound care solutions that can effectively address hemorrhage, infection, and pain outside of traditional clinical infrastructure. We developed a field-polymerizable hydrogel wound dressing capable of delivering tranexamic acid (hemostatic), vancomycin and tobramycin (broad-spectrum antibiotics), and lidocaine (analgesic) directly to the site of injury. Using computational modeling, we designed a lightweight, rugged hydrogel that polymerizes rapidly with potable water and conforms to irregular wound beds. The system demonstrated burst release of hemostatic and analgesic agents and sustained antibiotic release over four days. In vitro and in vivo testing confirmed the hydrogel{\textquoteright}s ability to stabilize clots, prevent fibrinolysis, and eradicate polymicrobial gram-positive and gram-negative bacterial infections in a murine model of open fracture. Large animal studies further validated its translational potential in a large, complex wound. This modular, multifunctional platform provides a field-ready solution for wound management in austere environments, with the potential to reduce infection, control bleeding, and improve wound stabilization when access to definitive care is delayed.",

author = "Pumford, \{Elizabeth A.\} and Hamad, \{Christopher D.\} and Enueme, \{Amaka I.\} and Zeinab Mamouei and Nicholas Peterson and Christopher Hart and Chad Ishmael and Alan Li and Rahul Sobti and Jack Pearce and Jeremiah Taylor and Micah Ralston and Wainwright, \{Jared D.\} and Kan Nakamoto and Perenlei Enkhbaatar and Cook, \{Kaitlyn A.\} and Francis, \{Kevin P.\} and John Adams and Alexandra Stavrakis and Wenke, \{Joseph C.\} and Kasko, \{Andrea M.\} and Bernthal, \{Nicholas M.\}",

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doi = "10.1038/s41598-026-37521-y",

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AU - Peterson, Nicholas

AU - Hart, Christopher

AU - Ishmael, Chad

AU - Li, Alan

AU - Sobti, Rahul

AU - Pearce, Jack

AU - Taylor, Jeremiah

AU - Ralston, Micah

AU - Wainwright, Jared D.

AU - Nakamoto, Kan

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AU - Cook, Kaitlyn A.

AU - Francis, Kevin P.

AU - Adams, John

AU - Stavrakis, Alexandra

AU - Wenke, Joseph C.

AU - Kasko, Andrea M.

AU - Bernthal, Nicholas M.

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Y1 - 2026/12

N2 - Traumatic injuries in resource-limited settings, such as remote, rural, or disaster-affected environments, require wound care solutions that can effectively address hemorrhage, infection, and pain outside of traditional clinical infrastructure. We developed a field-polymerizable hydrogel wound dressing capable of delivering tranexamic acid (hemostatic), vancomycin and tobramycin (broad-spectrum antibiotics), and lidocaine (analgesic) directly to the site of injury. Using computational modeling, we designed a lightweight, rugged hydrogel that polymerizes rapidly with potable water and conforms to irregular wound beds. The system demonstrated burst release of hemostatic and analgesic agents and sustained antibiotic release over four days. In vitro and in vivo testing confirmed the hydrogel’s ability to stabilize clots, prevent fibrinolysis, and eradicate polymicrobial gram-positive and gram-negative bacterial infections in a murine model of open fracture. Large animal studies further validated its translational potential in a large, complex wound. This modular, multifunctional platform provides a field-ready solution for wound management in austere environments, with the potential to reduce infection, control bleeding, and improve wound stabilization when access to definitive care is delayed.

AB - Traumatic injuries in resource-limited settings, such as remote, rural, or disaster-affected environments, require wound care solutions that can effectively address hemorrhage, infection, and pain outside of traditional clinical infrastructure. We developed a field-polymerizable hydrogel wound dressing capable of delivering tranexamic acid (hemostatic), vancomycin and tobramycin (broad-spectrum antibiotics), and lidocaine (analgesic) directly to the site of injury. Using computational modeling, we designed a lightweight, rugged hydrogel that polymerizes rapidly with potable water and conforms to irregular wound beds. The system demonstrated burst release of hemostatic and analgesic agents and sustained antibiotic release over four days. In vitro and in vivo testing confirmed the hydrogel’s ability to stabilize clots, prevent fibrinolysis, and eradicate polymicrobial gram-positive and gram-negative bacterial infections in a murine model of open fracture. Large animal studies further validated its translational potential in a large, complex wound. This modular, multifunctional platform provides a field-ready solution for wound management in austere environments, with the potential to reduce infection, control bleeding, and improve wound stabilization when access to definitive care is delayed.

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A field polymerizing hydrogel enables simultaneous antimicrobial, hemostatic, and analgesic delivery in traumatic wounds

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