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Current Insights And Recommendations For Tourniquet Use In Foot And Ankle Surgery – Part 1: Indications And Precautions

April 2021

Due to a lack of concise, standardized guidelines for implementation in foot and ankle surgery, these authors provide a literature review and extrapolate recommendations from existing data existing on safe lower extremity tourniquet use. This article will be a three-part series covering indications, complications and recommendations for use. 

First observed during the Roman Empire (199 BCE-500 CE), devices made of metals and leather controlled hemorrhagic bleeding from extremity amputations during combat.1 Later coined the tourniquet, these devices were a first-line life-saving measure. It was not until 1864 that tourniquets became an adjunct for good surgical technique (i.e. creating a bloodless surgical field).1 Fast-forward to modern day and tourniquet usage during podiatric surgical procedures is a widespread practice to facilitate surgical ease and good technique.

Despite advancements over time, the fundamental function of a tourniquet remains the same; to occlude blood flow distal to the application site. There are inherent risks involved when modifying any physiologic process. When dealing with combat situations and a ‘life over limb’ mentality, the risks of tourniquet usage may be negligible compared to the potential benefits. However, when tourniquet use facilitates surgical technique, limb quality and preservation of distal structures are a greater consideration.

With an extensive history of use in surgical specialties, tourniquet complications are well-known and can include: tissue ischemia, nerve injury, implication on infection rates and venous complications including deep vein thrombosis (DVT) and pulmonary embolism (PE).2 To mitigate tourniquet-associated complications, understanding appropriate use and practicing safe application techniques established through evidence-based research is essential. 

In the first part of this series of articles examining the literature on tourniquet use in surgery, we will address the relevant indications and contraindications. 

How Do Tourniquets Contribute To The Surgical Process?

Primary indications for tourniquet use in the surgical setting include:2

  • To limit blood loss/prevent hemorrhage;
  • To create a nearly bloodless surgical field;
  • Preparation for venipuncture; or
  • To confine a bolus of anesthetic in an extremity for intravenous regional anesthesia (IVRA, also known as a Bier Block) of the distal lower extremity.

While the first indication is well-established, the second indication (bloodless surgical field) is dependent on surgeon preference as dictated by perceived surgical outcomes. Some surgeons prefer to operate in a ‘wet field’ (i.e. without tourniquet use) for a variety of reasons and, if trained properly, can have optimal outcomes while avoiding potential tourniquet complications. However, with an estimated 15,000 surgical procedures performed daily using a tourniquet in the U.S., the probability of complications increase.1 The widespread tourniquet use has many potential benefits stemming from a nearly bloodless surgical field such as; decreased operative time, minimized risk of iatrogenic injury/tissue damage and decreased risk of infection.2,3

Key Considerations Regarding Tourniquet Contraindications                                        

Along with the adverse effects observed with improper application/use of a tourniquet, there are associated adverse effects innate to certain circumstances and patient populations with regards to tourniquet use. This makes careful patient selection a key factor in perioperative tourniquet outcome.

Current DVT in the ipsilateral surgical limb is an absolute contraindication for tourniquet use. Relative contraindications for using a tourniquet include: infection; sickle cell hemoglobinopathy; history of DVT/PE; documented hypercoagulability; open fracture; severe crush injuries; ipsilateral vascular graft application or recent revascularization; and peripheral vascular disease (PVD).2

Now let us take a closer look at the individual absolute and relative contraindications for tourniquet use. 

What You Should Know About Contraindications Related To DVT, PE And Infection 

Deep Vein Thrombosis (DVT). The only definite contraindication to tourniquet use and exsanguination found on literature review is the presence of a DVT, as tourniquet release may precipitate thrombus dislodgement and possible development of a pulmonary embolism (PE).4-6

Infection. The reluctance to use tourniquets in surgical cases with infection stems from the theoretical risk of dissemination of bacteria.6 However, this risk more closely associates with proximal spread of infection secondary to exsanguination rather than use of the tourniquet itself.7 Studies by Eyers and colleagues in 2000 and Wagner and team in 1983 displayed no increase in septic complications due to exsanguination or tourniquet use.4,5 Listed as a relative contraindication, surgeons can still use tourniquets proximal to the site of infection if desired.6

Previous DVT/PE/Hypercoagulability. A history of DVT or PE is a frequently-cited risk factor for subsequent recurrence of these conditions with future surgical procedures.8 The American College of Chest Physicians (ACCP) published a risk stratification to classify patients with regards to venous thromboembolism (VTE) recurrence:9

• High Risk: surgery within three months of the original DVT or PE;

• Moderate Risk: surgery between three and 12 months from the original DVT or PE; and

• Low Risk: surgery longer than 12 months from the original DVT or PE.9

Though foot and ankle procedures have been historically considered lower risk procedures with respect to VTE occurrence, there is still a high rate of VTE recurrence (22 to 29 percent) reported in literature.8 Application and duration of tourniquet use correlates to this development of DVT.10

Relevant Contraindications Related To Sickle Cell Pathology, Trauma And Vascular Disease

Sickle Cell Hemoglobinopathy (Sickle Cell Disease/Trait). In patients with sickle cell disease, circulatory stasis, hypoxia and acidosis beneath and distal to the tourniquet cuff create favorable conditions for the genesis of red cell sickling (precipitating a sickle cell crisis), increasing the risk of thrombosis, infarction and hemolysis.6,11 However, recent literature reviews suggest that, when strictly necessary and with appropriate perioperative measures in place, tourniquet use is relatively safe in most patients with sickle cell disease.12,13 These reviews also supports the notion that individuals with heterozygous gene mutation and sickle cell trait are less predisposed to adverse event risk with tourniquet use than those with sickle cell disease.12,13 It is important to note, though, that these reviews adamantly caution careful perioperative management in this patient group, paying extra attention to maintaining the correct patient temperature, acid-base status and oxygenation during the perioperative period.12,13

Indisputably, there exists some increased risk of provoking intravascular sickling of red blood cells with the use of an arterial tourniquet. Therefore, one should balance the risks of precipitating a sickle crisis from tourniquet use in patients with sickle cell disease against the benefit of operating in a bloodless field.

Open Fractures/Severe Crush Injuries. As one generally observes such injuries with higher energy mechanisms, tourniquet use in open fractures is a relatively contraindicated, as it may hinder the ability to adequately assess the extent and devascularization of the injury.9,14 The hypothesis also exists that, due to the precarious blood supply observed with crush injuries, tourniquet application may result in necrosis of potentially viable tissue.6

Ipsilateral Vascular Graft Application/Recent Revascularization. This relative contraindication for tourniquet use in ‘vascular-dependent circumstances’ is inclusive of prior arterial graft application and/or prior revascularization efforts. These contraindications primarily derive from the pathophysiology that occurs with tourniquet application; specifically, the compressive and ischemic injury that may result when initial occlusion (i.e. time of inflation) and subsequent reperfusion (i.e. time of deflation) of the vasculature occurs.2,15

For application of tourniquets to a previously re-vascularized area and/or ipsilateral area of vascular repair, the potential physiologic damage that can occur with pressure exerted by a tourniquet (collectively categorized as endothelial injury) creates a relative contraindication to its use in these circumstances.15,16 Though tourniquet use in this patient population appears controversial, there are recommendations cited in vascular-based literature that advocate a minimum of six weeks prior to using a tourniquet directly over an arterial repair or in the ipsilateral lower extremity.15,16 This will permit enough time for the vascular repair to mature and decrease risk of thrombolytic events.15,16

While a few studies have examined tourniquet use in lower extremity procedures in patients with previous revascularization, there is a paucity of data and a relative absence of randomized, controlled trials directly correlating tourniquet usage to arterial graft occlusion or failure of re-vascularized vessels. Until research on the subject progresses and evidence based-guidelines are established and reported in the literature, these ‘vascular-dependent circumstances’ remain a relative contraindication to tourniquet use, warranting input from our vascular colleagues.  

Peripheral Arterial Disease (PAD). Existing literature deems the presence of calcified vessels a relative contraindication to tourniquet use secondary to, essentially, incompressible vessels.6 When applied to vessels that are difficult to compress, such that as observed in patients with Mönckeberg medial calcific sclerosis, the use of a tourniquet primarily produces venous occlusion, resulting in increased bleeding.16 Furthermore, if one increases the tourniquet pressure to effectively occlude the atherosclerotic vessels, the higher pressure predisposes the vessel to higher probabilities of injury. This might include fracturing the vessel wall and further producing an acute occlusion of a previously patent vessel.6,14,16 From prior citations, this theory of PAD as a contraindication has been propagated without much evidenced based literature. 

In 2016, Woelfle-Roos and colleagues conducted an in-depth analysis of tourniquet safety in patients with radiographic evidence of calcific vascular disease.17 Results demonstrated important differences between the types of calcific arterial disease (medial or intimal) and the associated complications. Compared with medial-type calcifications, patients with intimal-type calcifications displayed a 3.2-fold increased probability of minor ischemic complications (such as protracted healing), though the authors could not directly connect this complication to tourniquet use.17 Due to inconclusive evidence, PAD remains a relative contraindication warranting a thorough preoperative work-up in this patient population.

Dr. Wilson is a third-year Podiatric Medicine and Surgery resident at St. Mary’s Medical Center in San Francisco, Calif.

Dr. Oloff is the Podiatric Medicine and Surgery Residency Program Director at St. Mary’s Medical Center in San Francisco, Calif. He is an attending physician at the Palo Alto Medical Foundation in Burlingame, Calif.

1. Noordin S, McEwen J, Kragh JF, Eisen A, Masri BA. Surgical tourniquets in orthopaedics. J Bone Joint Surg Am. 2009;91(12);2958–2967.

2. Jensen J, Hicks RW, Labovitz J. Understanding and Optimizing Tourniquet Use During Extremity Surgery. AORN J. 2019;109(2):171-182. 

3. Saied A, Zyaei A. Tourniquet use during plating of acute extra-articular tibial fractures: effects on final results of the operation. J Trauma. 2010;69(6):E94–97. 

4. Eyers P, Ashley S, Scott DJA. Tourniquets in arterial bypass surgery. Eur J Vasc Endovasc Surg. 2000;20(2):113–117.

5. Wagner WH, Treiman RL, Cossman DV, et al. Tourniquet occlusion technique for tibial artery reconstruction. J Vasc Surg. 1993;18(4):637-647.

6. Fletcher IR, Healy TE. The arterial tourniquet. Ann R Coll Surg Engl. 1983;65(6):409-417.

7. Vaughan A, Hardwick T, Gaskin J, Bendall S. Tourniquet use in orthopaedic surgery. Orthop Trauma. 2017;31(5):312-315.

8. Liem TK, Huynh TM, Moseley SE, et al. Symptomatic perioperative venous thromboembolism is a frequent complication in patients with a history of deep vein thrombosis. J Vasc Surg. 2010;52(3):651-657.

9. Douketis JD, Berger PB, Dunn AS, et al. The perioperative management of antithrombotic therapy: American College of Chest Physicians Evidence-Based Clinical Practice Guidelines (8th Edition). Chest. 2008;133(6 Suppl):299S-339S.

10. Sullivan M, Dominiq-Eusebio I, Haigh K, Paulo-Panti J, Omari A, Hang J. Prevalence of deep vein thrombosis in low-risk patients after elective foot and ankle surgery. Foot Ankle Int. 2019;40(3):330-335. 

11. Kam PC, Kavanagh R, Yoong FF. The arterial tourniquet: pathophysiological consequences and anaesthetic implications. Anaesthesia. 2001;56(6):534-545.

12. Pignatti M, Zanella S, Borgna-Pignatti C. Can the surgical tourniquet be used in patients with sickle cell disease or trait? A review of the literature. Expert Rev Hematol. 2017;10(2):175-182. 

13. Fisher B, Roberts CS. Tourniquet use and sickle cell hemoglobinopathy: how should we proceed? South Med J. 2010;103(11):1156-1160.

14. Khan A, Gray A. Tourniquet uses and precautions. Surgery. 2010;29(2):73-75.

15. Ducic I, Chang S, Dellon AL. Use of the tourniquet in reconstructive surgery in patients with previous ipsilateral lower extremity revascularization: Is it safe? A survey. J Recon Microsurg. 2006;22(3):183-189.

16. Jeyaseelan S, Stevenson TM, Pfitzner J. Tourniquet failure and arterial calcification. Anaesthesia. 1981;36:48-50.

17. Woelfle-Roos JV, Dautel L, Wernerus D, Woel e KD, Reichel H. Vascular calcifications on the pre-operative radiograph: predictor of ischemic complications in total knee arthroplasty? J Arthroplasty. 2016;31(5):1078-1082.

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