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The Certification Matters: A Comparative Performance Analysis of Combat Application Tourniquets versus Non-Certified CAT Look-Alike Tourniquets

Published online by Cambridge University Press:  22 August 2023

Emanuele Lagazzi Open the ORCID record for Emanuele Lagazzi [Opens in a new window] ,
Giulia Ballardini ,
Alberto Drogo ,
Ludovica Viola ,
Eva Marrone ,
Valerio Valente ,
Michele Bonetti ,
Jarone Lee ,
David R. King  and
Serena Ricci
Emanuele Lagazzi*
Affiliation:
Department of Surgery, Humanitas Research Hospital, Rozzano, Lombardia, Italy Division of Trauma, Emergency General Surgery, and Surgical Critical Care, Department of Surgery, Massachusetts General Hospital, Harvard Medical School, Boston, Massachusetts USA Italian Trauma League ODV, Genova, Italy
Giulia Ballardini
Affiliation:
Department of Informatics, Bioengineering, Robotics, and Systems Engineering, University of Genova, Genova, Italy Max Planck Institute for Intelligent Systems, Stuttgart, Germany
Alberto Drogo
Affiliation:
Italian Trauma League ODV, Genova, Italy School of Medical and Pharmaceutical Sciences, University of Genova, Genova, Italy
Ludovica Viola
Affiliation:
Department of Informatics, Bioengineering, Robotics, and Systems Engineering, University of Genova, Genova, Italy
Eva Marrone
Affiliation:
Italian Trauma League ODV, Genova, Italy School of Medical and Pharmaceutical Sciences, University of Genova, Genova, Italy
Valerio Valente
Affiliation:
Italian Trauma League ODV, Genova, Italy Department of Anesthesia and Intensive Care Unit, University of Modena and Reggio Emilia, Modena, Emilia-Romagna, Italy
Michele Bonetti
Affiliation:
Italian Trauma League ODV, Genova, Italy Schwarzwald-Baar Klinikum, University Hospital of the University of Freiburg - Division of Anesthesia and Intensive - Emergency and Pain Medicine Villingen-Schwenningen, Freiburg, Baden-Württemberg, Germany
Jarone Lee
Affiliation:
Division of Trauma, Emergency General Surgery, and Surgical Critical Care, Department of Surgery, Massachusetts General Hospital, Harvard Medical School, Boston, Massachusetts USA
David R. King
Affiliation:
Division of Trauma, Emergency General Surgery, and Surgical Critical Care, Department of Surgery, Massachusetts General Hospital, Harvard Medical School, Boston, Massachusetts USA
Serena Ricci
Affiliation:
Department of Informatics, Bioengineering, Robotics, and Systems Engineering, University of Genova, Genova, Italy Simulation and Advanced Education Center, University of Genova, Genova, Liguria, Italy
*
Correspondence: Emanuele Lagazzi, MD Division of Trauma, Emergency Surgery, and Surgical Critical Care Massachusetts General Hospital 165 Cambridge St, Suite 810 Boston, Massachusetts 02114 USA E-mail: [email protected]
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Abstract

Introduction:

The Stop the Bleed campaign provided civilians with tourniquet application training and increased the demand for tourniquets among the general population, which led to the development of new commercially available devices. However, most widely available tourniquets have not undergone testing by regulatory bodies and their efficacy remains unknown.

Study Objective:

This study aimed to compare the efficacy and performance of Combat Application Tourniquets (CAT) versus uncertified tourniquets.

Methods:

This study compared 25 CAT with 50 commercially available “look-alike” tourniquets (LA-TQ) resembling the CAT. The CAT and the LA-TQ were compared for cost, size, and tested during one-hour and six-hour applications on a manikin’s leg. The outcomes were force applied, force variation during the application, and tourniquet rupture rate.

Results:

The LA-TQ were cheaper (US$6.07 versus US$27.19), shorter, and had higher inter-device variability than the CAT (90.1 [SE = 0.5] cm versus 94.5 [SE = 0.1] cm; P <.001). The CAT applied a significantly greater force during the initial application when compared to the LA-TQ (65 [SE = 3] N versus 14 [SE = 1] N; P <.001). While the initial application force was maintained for up to six hours in both groups, the CAT group applied an increased force during one-hour applications (group effect: F [1,73] = 105.65; P <.001) and during six-hour applications (group effect: F [1,12] = 9.79; P = .009). The rupture rate differed between the CAT and the LA-TQ (0% versus 4%).

Conclusion:

The LA-TQ applied a significantly lower force and had a higher rupture rate compared to the CAT, potentially affecting tourniquet performance in the context of public bleeding control. These findings warrant increased layperson education within the framework of the Stop the Bleed campaign and further investigations on the effectiveness of uncertified devices in real-world applications.

Keywords

bleedinghemorrhageprehospitalStop the Bleedtourniquet
Type
Original Research
Information
Prehospital and Disaster Medicine , Volume 38 , Issue 4 , August 2023 , pp. 450 - 455
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Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of the World Association for Disaster and Emergency Medicine

Introduction

To date, hemorrhage remains the first cause of potentially preventable death in trauma. Reference Eastridge, Holcomb and Shackelford1 For life-threatening bleeding originating from the limbs, tourniquets are used in the prehospital setting, often allowing the patient to reach the hospital alive. Reference Richey2Reference Kragh, Littrel and Jones4 Proper use of tourniquets is associated with increased systolic blood pressure on arrival to the emergency department, decreased use of blood products, and lower incidence of limb-related complications, which may lead to improved long-term outcomes and increased survival in trauma patients. Reference Smith, Ochoa and Wong5,Reference Covey and Gentchos6

Traditionally, tourniquets have been used in military settings and by Emergency Medical Services; however, there is strong evidence in the literature supporting their use by non-medical personnel. Reference Lee, Porter and Hodgetts7Reference Teixeira, Brown and Emigh13 To spread awareness about the importance of using antihemorrhagic devices, in 2015, the American College of Surgeons (ACS; Chicago, Illinois USA) launched the Stop the Bleed campaign. Reference Rasmussen, Baer and Goolsby14,15 Its main aim is to train bystanders to act as immediate responders and treat massive external bleeding in emergency settings. Reference Goolsby, Jacobs and Hunt16 Since the training program’s inception, over 117,222 accredited instructors have held more than 134,510 classes in 118 different counties, certifying more than 2.4 million people as Stop the Bleed providers. 17

These recent efforts by the ACS have increased interest in tourniquets among civilians, and as more and more people are trained, it is reasonable to assume that the demand for tourniquet purchases by the non-medical civilian populations will continue to increase. However, due to the multitude of manufacturers, the majority of tourniquets available online are not recommended by the Committee on Tactical Combat Casualty Care (CoTCCC; Fort Sam Houston, Texas USA), have not obtained the Conformité Européenne (CE) marking, and have not been certified by the US Food and Drug Administration (FDA; Silver Spring, Maryland USA). Sparse anecdotal evidence and media coverage have reported the risk of “catastrophic failure” and reduced effectiveness in stopping limb hemorrhage when using counterfeit tourniquets. Reference Pegues18,Reference Elliott19 However, despite the diffusion of unlicensed models in the market and their use especially among the civilian population, the resilience and efficacy of uncertified tourniquets remain unclear. This study aims to compare CoTCCC-recommended and FDA/CE-certified Combat Application Tourniquets (CAT) Generation 7 tourniquets (CAT Resources, LLC; Rock Hill, South Carolina USA) with uncertified CAT look-alike tourniquets (LA-TQ) for differences in cost, length, force applied, force variation, and rupture rate.

Methods

The CAT consists of an external rod that rotates and allows an increasing circumferential pressure to the limb through a windlass system (Figure 1). When the pressure exerted on the limb is greater than the intravascular pressure, the blood flow is stopped. The CAT was selected for three main reasons: (1) they are one of the oldest commercial tourniquets, thus making them easy to find on the market, both in their certified and uncertified versions; (2) the CAT is one of the recommended tourniquets for the Stop the Bleed program and is included in public access Stop the Bleed kits; and (3) they are widely available world-wide. Reference Kragh, Burrows and Wasner2022 The LA-TQ were selected based on visual appearance and immediate availability during an online search. Certified tourniquets are defined as tourniquets that have been certified by the FDA and marked with the sign of CE. For the LA-TQ sample, the absence of CE certification was assessed by visually inspecting the devices and the material provided by the manufacturer for the CE marking, and by searching for the devices, using the device name and manufacturer, on European online databases containing a list of CE-certified products. 23,24 To verify the devices’ lack of FDA approval, an online search of the LA-TQ was conducted using the FDA catalog of cleared and approved medical devices. 25 Tourniquets without FDA approval and CE certification were considered uncertified and could be included in the study. To ensure the generalizability of this study’s findings, the two groups of LA-TQ were purchased from two different vendors in two widely used and internationally available e-commerce retail platforms (Amazon [Seattle, Washington USA] and AliExpress [Hangzhou, Zhejiang, China]). After comparing the two groups for length and cost (ie, 25 CAT and 50 LA-TQ), all tourniquets were tested on a manikin’s leg. Tourniquet length (ie, the length of the strap, excluding the buckle) was assessed before each single-use application. During the application, the rupture rate, the force applied at the time of application, and its variability during one-hour and six-hour applications were measured. Tourniquet rupture was defined as complete mechanical failure (ie, breakage of the windlass, c-clip, or strap) during the positioning or application of the tourniquet. The rupture rate was calculated as the ratio between the tourniquets that suffered complete mechanical failure and the total number of same-type tourniquets used.

Figure 1. (a) Tourniquets Used in the Study, a Combat Application Tourniquet (top), and Two CAT Look-Alike Tourniquets (LA-TQ) (bottom and center); (b) Experimental Setup; and (c) Sensor Disposition: A Total of Eight Force Sensors were Positioned on Two Lower Limbs of a Manikin (four sensors per limb).

For measuring the force applied by the tourniquets, the setup described by Viola and colleagues was used. Reference Viola, Lagazzi and Ballardini26 Eight force-sensing resistors (FSR 402; Interlink Electronics; Camarillo, California USA) were positioned on the two lower limbs of a medical-grade manikin, below the groin (Figure 1). All tourniquets were positioned on the force-sensing resistors by Stop the Bleed instructors: the strap was tightened until no slack was appreciated between the tourniquet and the mannequin’s leg; the windlass rod was left free from the c-clip and kept perpendicular to the longitudinal axis of the mannequin’s leg until it was time to perform the windlass turns. Following tourniquet positioning, three clockwise 180-degree windlass turns were performed. The number of turns was decided based on evidence in the literature indicating that three turns are effective in obliterating the dorsalis pedis pulse at Doppler auscultation during most lower-limb applications. Reference Weppner, Lang, Sunday and Debiasse27 Each application lasted either one hour (20 CAT and 41 LA-TQ) or six hours (five CAT and nine LA-TQ), and force was recorded from the positioning to the end of the session at a sampling frequency of 1Hz. The force of each tourniquet was obtained by averaging the data from three sensors (ie, excluding the one under the plastic stabilization plate). Reference Viola, Lagazzi and Ballardini26 To compare the performance of the two groups of devices in the one-hour session, the averaged force after the application (five minutes after the third turn, h0) and at the end of the session (ie, the last five minutes, h1) were computed for each tourniquet. Further investigation was conducted to determine whether the applied force changed when the tourniquet was left in place for six hours. For each device tested in the six-hour sessions, the force was averaged in the last five minutes of each hour (h1 to h6).

Statistical Analysis

All the data were analyzed using Matlab R2021b (The MathWorks Inc.; Natick, Massachusetts USA) and SPSS Statistics 25 (IBM Corp.; Armonk, New York USA). Length difference was assessed using unpaired t-test. To analyze the force applied during the one-hour and six-hour sessions, a repeated-measure ANOVA was performed. The main effects included “Group” (two levels: CAT and LA-TQ) and “Time” (two levels for the one-hour session; six levels for the six-hour session) as between and within factors, respectively. Before running the ANOVAs, the normality of the data was assessed using the Anderson–Darling test; since the null hypothesis was rejected, the data were normalized using the fractional rank method. Reference Templeton28 Sphericity was also tested using Mauchly’s test, and when it was rejected (ie, six-hour recordings), the Greenhouse–Geisser correction was applied. Statistical significance was set at the family-wise error rate of α = 0.05.

Results

A total of 75 tourniquets, of which 25 CAT and 50 LA-TQ, were included in this study. As the tourniquet size is one of the parameters evaluated by the CoTCCC, the length of the CAT and LA-TQ prior to the application was assessed. Compared to the CAT, the LA-TQ were significantly shorter and had higher variability (CAT: mean 94.5 [SE = 0.1] cm; LA-TQ: 90.1 [SE = 0.5] cm; P <.001). The LA-TQ were cheaper than the CAT (mean price per device: US$6.07 versus US$27.19). Out of 75 devices tested, two of the LA-TQ and zero of the CAT broke during the positioning (4% versus 0%; Figure 2).

Figure 2. Bar Graph Showing the Differences in Price, Length, Rupture Rate, and Force Applied between Combat Application Tourniquets (CAT) and CAT Look-Alike Tourniquets (LA-TQ).

Note: *** indicates P <.001.

Analysis of one-hour recordings revealed that the force applied was significantly different in the two groups, with greater forces applied by the CAT compared to the LA-TQ (CAT: 65 [SE = 3] N; LA-TQ: 14 [SE = 1] N; group effect: F [1,73] = 105.65; P <.001); Table 1. Interestingly, the force applied increased significantly over time only in the CAT group (time effect: F [1,71] = 4.08; P = .047; time*group effect: F [1,71] = 11.36; P = .001). Analysis on a subset of devices (five CAT and nine LA-TQ) positioned for six hours showed similar results. During the six-hour sessions, the CAT applied greater force than the LA-TQ (group effect: F [1,12] = 9.79; P = .009; Figure 3). Nevertheless, both groups did not lose application force for the entire duration of the session (time effect: F [1.32,15.85] = 2.38; P = .138; time*group effect: F [1.32,15.85] = 2.63; P = .117).

Table 1. Force Applied by the Two Groups of Tourniquets (mean [SE]) at the Beginning (h0, namely first five minutes after the third turn) and the End of the One-Hour Application (h1, minutes 55 to 60)

Abbreviations: CAT, Combat Application Tourniquet; LA-TQ, look-alike tourniquets.

Figure 3. Force Applied by the Two Tourniquet Types during the Six-Hour Application.

Note: The points show the mean force computed averaging the last five minutes of each hour (h1-h6); the bars indicate the standard error of the mean of the force recorded. ** indicates P <.01.

Abbreviations: CAT, Combat Application Tourniquet; LA-TQ, look-alike tourniquets.

Discussion

When compared to the CAT, the LA-TQ were cheaper, shorter, had a higher rupture rate, and applied reduced force. While in both groups the initial application force was maintained throughout the experiment, the CAT demonstrated an increase in applied force during the observation compared to the LA-TQ.

Currently, uncontrolled limb bleeding remains a leading cause of preventable death, Reference Davis, Satahoo and Butler29 with tourniquets playing a major role in managing life-threatening extremity hemorrhage in the prehospital setting. Regardless of the type or mechanism of action, the tourniquet’s main function is to apply on the limb a circumferential pressure superior to the arterial pressure, thus obliterating arterial flow to the extremity. Even in certified devices, the application of insufficient force by the tourniquet due to incorrect application (eg, too much slack, insufficient windlass turns, or incorrect positioning) is associated with increased blood loss, major limb complications, and limb loss. Reference Inaba, Siboni and Resnick12,Reference Polston, Clumpner, Kragh, Jones, Dubick and Billings30Reference King, van der Wilden, Kragh and Blackbourne35 Namely, insufficient application force can result in the failure of obliterating the distal arterial blood flow while blocking venous return from the limb, which may lead to venous tourniquet application with paradoxical bleeding, limb edema, and compartment syndrome. Reference King, van der Wilden, Kragh and Blackbourne35,Reference Mikdad, Mokhtari and Luckhurst36 The findings of this study show that the LA-TQ applied a significantly lower force than the CAT, despite optimal tourniquet application by Stop the Bleed instructors in a controlled setting. While it remains unclear if the difference in the applied force between the two cohorts is due to the use of different materials in the main tourniquet components or to subtle mechanical differences, it is reasonable to assume that the LA-TQ application by untrained personnel in an emergent setting might lead to an even lower application force than what was reported in this study. While the use of tourniquets is not without risks, there is strong evidence in the literature supporting the use of appropriately positioned certified tourniquets in the setting of life-threatening extremity hemorrhage. Reference Richey2,Reference Smith, Ochoa and Wong5,Reference Eilertsen, Winberg, Jeppesen, Hval and Wisborg11 Conversely, the use of uncertified tourniquets unable to reach an adequate pressure could potentially lead to adverse outcomes, especially in the context of wide-spread public use. In this framework, complete mechanical failure of the tourniquet could further decrease the chances of achieving bleeding control in life-threatening limb hemorrhages. While there are limited data in the literature regarding failure to control the bleeding following tourniquet rupture, Weppner and colleagues showed that mechanical failure, defined as the rupture of one of the tourniquet key components, was associated in all cases with the inability to stop the distal pulse. Reference Weppner, Lang, Sunday and Debiasse27 In the present study, the LA-TQ had a higher rupture rate compared to the CAT. The observed difference in rupture rates between the cohorts, due to the implications of a complete mechanical failure in the setting of life-threatening hemorrhage, strongly supports the need for further testing of what devices are available to the public and advocates for increased layperson education on the use of uncertified devices.

The CoTCCC process to evaluate commercial tourniquets is based on a multi-parameter scoring that includes the effectiveness of arterial occlusion; speed and easiness of application; optimal occlusion pressure; size and weight; occurrence of published complications, failures, or safety issues of devices; and combat usage reports, civilian usage reports, and user preferences in literature. Reference Shackelford, Butler and Kragh8 In the present study, the straps of the LA-TQ were significantly shorter compared to the CAT. While there is a paucity of data in the literature regarding the impact of strap length on tourniquet efficacy, it can be presumed that for the tourniquet to be secured through the buckle, the strap length should be superior to the circumference of the limb. In a study conducted on the US military population, the average thigh circumferences ranged from 49cm to 77cm. Reference Gordon, Churchill and Clauser37 Within this specific population, the strap lengths of both the LA-TQ and the CAT would be greater than the limb circumference. However, it must be noted that due to the increased prevalence of obesity in the civilian population, further studies need to be done to assess if shorter straps might have detrimental effects on tourniquet use, especially in lower limb applications. Reference Stierman, Afful and Carrol38

Limitations

Several limitations must be considered. All tourniquet applications were performed on a simulated limb in a controlled setting. While the use of a manikin allowed for prolonged application times, future studies should replicate the present results in a more realistic scenario, such as in perfused models. Another limitation concerns the fact that the tourniquet applicators were not blinded to the tourniquet type they were using due to the small visual differences (ie, the printed logo on the strap, and the raised lettering in the strap buckle and windlass rod). To ensure optimal tourniquet application despite this limitation, five Stop the Bleed instructors were enrolled to position the devices. Furthermore, the number of LA-TQ tested was twice the number of the CAT (50 versus 25). During the design phase, to increment the generalizability of the present study’s findings, two groups of 25 LA-TQ devices were purchased from two distinct high-volume vendors. However, since the two groups’ price, visual aspect, and commercial availability were nearly identical, the decision was made to pool all LA-TQ devices within one group, regardless of the vendor. This is supported by one of the results of this study, as the standard error of the mean force applied by all LA-TQ was as low as 1N, suggesting that they applied a similar force. Lastly, it was not possible to include in this study all types of LA-TQ currently available online, as this number is high and constantly increasing. For the purposes of this exploratory study, the choice was made to include two tourniquets that are immediately available to the general public on two international and widely used e-commerce platforms. Future studies will be required to: (1) determine whether the LA-TQ could produce the same force as the CAT devices, with a higher number of turns, without breaking; (2) assess whether laypersons can safely and effectively position the LA-TQ; and (3) determine physical and mechanical properties of the LA-TQ.

Conclusion

The LA-TQ applied a significantly lower force and had a higher rupture rate than the CAT, potentially affecting tourniquet performance in the context of public bleeding control. Due to the increased availability of uncertified tourniquets to non-medical users, the Stop the Bleed campaign would be the optimal framework to provide increased layperson education regarding the use of certified devices. Lastly, these findings warrant additional investigations on the effectiveness of uncertified devices in real-world applications.

Conflicts of interest/funding

The authors have no conflict of interest to disclose. No external funding was obtained for the realization of this study.

Acknowledgments

This study was conducted primarily by members of the Italian Trauma League, a non-profit organization with the main goal of furthering trauma-related knowledge and education. The authors thank Giorgio Carlini for his help in designing the measurement tool, and Maura Casadio and Marco Chirico for their support in the design and data acquisition phases.

Authors Contributions

EL and MB designed the study; GB, LV, and SR designed and implemented the measurement tool; EL, AD, LV, EM, VV, MB, and SR ran the experiments; GB, LV, and SR analyzed the data; EL, AD, GB, EM, VV, MB, DK, JL, and SR wrote and revised the manuscript.

Footnotes

Note: Drs. E. Lagazzi and G. Ballardini contributed equally to this manuscript.

References

Eastridge, BJ, Holcomb, JB, Shackelford, S. Outcomes of traumatic hemorrhagic shock and the epidemiology of preventable death from injury. Transfusion (Paris). 2019;59(S2):14231428.CrossRefGoogle ScholarPubMed
Richey, SL. Tourniquets for the control of traumatic hemorrhage: a review of the literature. World J Emerg Surg. 2007;2(1):28.CrossRefGoogle ScholarPubMed
Galante, JM. Using tourniquets to stop bleeding. JAMA. 2017;317(14):1490.CrossRefGoogle ScholarPubMed
Kragh, JF, Littrel, ML, Jones, JA, et al. Battle casualty survival with emergency tourniquet use to stop limb bleeding. J Emerg Med. 2011;41(6):590597.CrossRefGoogle ScholarPubMed
Smith, AA, Ochoa, JE, Wong, S, et al. Prehospital tourniquet use in penetrating extremity trauma: decreased blood transfusions and limb complications. J Trauma Acute Care Surg. 2019;86(1):4351.CrossRefGoogle ScholarPubMed
Covey, DC, Gentchos, CE. Field tourniquets in an austere military environment: a prospective case series. Injury. 2022;53(10):32403247.CrossRefGoogle Scholar
Lee, C, Porter, KM, Hodgetts, TJ. Tourniquet use in the civilian prehospital setting. Emerg Med J. 2007;24(8):584587.CrossRefGoogle ScholarPubMed
Shackelford, SA, Butler, FK Jr, Kragh, JF Jr, et al. Optimizing the use of limb tourniquets in Tactical Combat Casualty Care: TCCC Guidelines Change 14-02. J Special Ops Med. 2015;15(1):1731.CrossRefGoogle ScholarPubMed
Mawhinney, AC, Kirk, SJ. A systematic review of the use of tourniquets and topical hemostatic agents in conflicts in Afghanistan and Iraq. Journal of the Royal Navy Medical Service. 2015;101(2):147154.CrossRefGoogle ScholarPubMed
Latina, R, Iacorossi, L, Fauci, A, et al. Effectiveness of prehospital tourniquet in emergency patients with major trauma and uncontrolled hemorrhage: a systematic review and meta-analysis. Int J Environ Res Public Health. 2021;18(23):12861.CrossRefGoogle ScholarPubMed
Eilertsen, KA, Winberg, M, Jeppesen, E, Hval, G, Wisborg, T. Prehospital tourniquets in civilians: a systematic review. Prehosp Disaster Med. 2021;36(1):8694.CrossRefGoogle ScholarPubMed
Inaba, K, Siboni, S, Resnick, S, et al. Tourniquet use for civilian extremity trauma. J Trauma Acute Care Surg. 2015;79(2):232237.CrossRefGoogle ScholarPubMed
Teixeira, PGR, Brown, CVR, Emigh, B, et al. Civilian prehospital tourniquet use is associated with improved survival in patients with peripheral vascular injury. J Am Coll Surg. 2018;226(5):769776e1.CrossRefGoogle ScholarPubMed
Rasmussen, TE, Baer, DG, Goolsby, C. The giving back. J Trauma Acute Care Surg. 2016;80(1):166167.CrossRefGoogle ScholarPubMed
JEMS Staff. What the White House’s Stop the Bleed Campaign Means for EMS. https://www.jems.com/patientcare/trauma/what-the-white-house-s-stop-the-bleed-campaignmeans-for-ems/. Accessed February 26, 2023.Google Scholar
Goolsby, C, Jacobs, L, Hunt, RC, et al. Stop the Bleed Education Consortium: education program content and delivery recommendations. J Trauma Acute Care Surg. 2018;84(1):205210.CrossRefGoogle ScholarPubMed
Stop the Bleed Program. https://www.stopthebleed.org/. Accessed February 24, 2023.Google Scholar
Pegues, J. Beware: counterfeit tourniquets could cost lives. CBS news. https://www.cbsnews.com/news/counterfeit-tourniquets-could-cause-catastrophic-consequences/. August 13, 2015. Accessed April 5, 2023.Google Scholar
Elliott, S. Bogus Tourniquets Could Endanger Lives in Combat. ∼https://mrdc.health.mil/index.cfm/media/articles/2010/bogus_tourniquet#:∼:text=%22The%20danger%20is%20if%20someone,often%20an%20arm%20or%20leg. Accessed April 5, 2023.Google Scholar
Kragh, JF, Burrows, S, Wasner, C, et al. Analysis of recovered tourniquets from casualties of Operation Enduring Freedom and Operation New Dawn. Mil Med. 2013;178(7):806810.CrossRefGoogle ScholarPubMed
McCarty, JC, Hashmi, ZG, Herrera-Escobar, JP, et al. Effectiveness of the American College of Surgeons Bleeding Control Basic Training among laypeople applying different tourniquet types. JAMA Surgery. 2019;154(10):923.CrossRefGoogle ScholarPubMed
Stop the Bleed Program. https://www.bleedingkits.org/all-products.html. Accessed February 24, 2023.Google Scholar
European Commission. EUDAMED- European Database on Medical Devices. https://ec.europa.eu/tools/eudamed/#/screen/home. Accessed March 5, 2023.Google Scholar
TUV Rheinland. Certipedia - Certificate Database from TÜV Rheinland. https://www.certipedia.com/?locale=en. Accessed March 1, 2023.Google Scholar
US Food and Drug Administration. Devices@FDA catalog of cleared and approved medical devices. https://www.accessdata.fda.gov/scripts/cdrh/devicesatfda/index.cfm. Accessed March 7, 2023.Google Scholar
Viola, L, Lagazzi, E, Ballardini, G, et al. Design of a system to detect the force applied by tourniquets in a manikin’s limb. 2021 43rd Annual International Conference of the IEEE Engineering in Medicine & Biology Society (EMBC). IEEE; 2021:5019-5022.CrossRefGoogle Scholar
Weppner, J, Lang, M, Sunday, R, Debiasse, N. Efficacy of tourniquets exposed to the Afghanistan combat environment stored in individual first aid kits versus on the exterior of plate carriers. Mil Med. 2013;178(3):334337.CrossRefGoogle Scholar
Templeton, G. A Two-step approach for transforming continuous variables to normal: implications and recommendations for IS research. Communications of the Association for Information Systems. 2011;28:4158.CrossRefGoogle Scholar
Davis, JS, Satahoo, SS, Butler, FK, et al. An analysis of prehospital deaths. J Trauma Acute Care Surg. 2014;77(2):213218.CrossRefGoogle ScholarPubMed
Polston, RW, Clumpner, BR, Kragh, JF, Jones, JA, Dubick, MA, Billings, S. No slackers in tourniquet use to stop bleeding. J Special Ops Med. 2013;13(2):12.CrossRefGoogle ScholarPubMed
Baruch, EN, Kragh, JF, Berg, AL, et al. Confidence–competence mismatch and reasons for failure of non-medical tourniquet users. Prehosp Emerg Care. 2017;21(1):3945.CrossRefGoogle ScholarPubMed
Nachman, D, Benov, A, Shovali, A, et al. Slack reducing band improves Combat Application Tourniquet pressure profile and hemorrhage control rate. Mil Med. 2017;182(S1):5358.CrossRefGoogle ScholarPubMed
King, DR, Larentzakis, A, Ramly, EP. Tourniquet use at the Boston Marathon bombing. J Trauma Acute Care Surg. 2015;78(3):594599.CrossRefGoogle ScholarPubMed
Kauvar, DS, Dubick, MA, Walters, TJ, Kragh, JF. Systematic review of prehospital tourniquet use in civilian limb trauma. J Trauma Acute Care Surg. 2018;84(5):819825.CrossRefGoogle ScholarPubMed
King, DR, van der Wilden, GM, Kragh, JF, Blackbourne, LH. Forward assessment of 79 prehospital battlefield tourniquets used in the current war. J Special Ops Med. 2012;12(4):33.CrossRefGoogle ScholarPubMed
Mikdad, S, Mokhtari, AK, Luckhurst, CM, et al. Implications of the national Stop the Bleed campaign: the swinging pendulum of prehospital tourniquet application in civilian limb trauma. J Trauma Acute Care Surg. 2021;91(2):352360.CrossRefGoogle ScholarPubMed
Gordon, C, Churchill, T, Clauser, CE, et al. Anthropometric Survey of US Army Personnel: Methods and Summary Statistics, Final Report October 1, 1988 to March 24, 1989. Natick, Massachusetts, US Army Natick Research Development and Engineering Center, OH. Published online March 1, 1988. Accessed April 5, 2023.Google Scholar
Stierman, B, Afful, J, Carrol, M, et al. National Health and Nutrition Examination Survey 2017–March 2020 Pre-pandemic Data Files Development of Files and Prevalence Estimates for Selected Health Outcomes. National Center for Health Statistics (US). https://stacks.cdc.gov/view/cdc/106273. 2021; NHSR No. 158. Accessed April 5, 2023.Google Scholar
Figure 0

Figure 1. (a) Tourniquets Used in the Study, a Combat Application Tourniquet (top), and Two CAT Look-Alike Tourniquets (LA-TQ) (bottom and center); (b) Experimental Setup; and (c) Sensor Disposition: A Total of Eight Force Sensors were Positioned on Two Lower Limbs of a Manikin (four sensors per limb).

Figure 1

Figure 2. Bar Graph Showing the Differences in Price, Length, Rupture Rate, and Force Applied between Combat Application Tourniquets (CAT) and CAT Look-Alike Tourniquets (LA-TQ).Note: *** indicates P <.001.

Figure 2

Table 1. Force Applied by the Two Groups of Tourniquets (mean [SE]) at the Beginning (h0, namely first five minutes after the third turn) and the End of the One-Hour Application (h1, minutes 55 to 60)

Figure 3

Figure 3. Force Applied by the Two Tourniquet Types during the Six-Hour Application.Note: The points show the mean force computed averaging the last five minutes of each hour (h1-h6); the bars indicate the standard error of the mean of the force recorded. ** indicates P <.01.Abbreviations: CAT, Combat Application Tourniquet; LA-TQ, look-alike tourniquets.