|Year : 2017 | Volume
| Issue : 1 | Page : 1-3
The evolution and future of combat casualty care
Bipin Puri VSM, PHS
Director General Medical Services, (Army), Delhi, India
|Date of Web Publication||17-Aug-2017|
Lt Gen Bipin Puri
Director General Medical Services, (Army), Delhi
Source of Support: None, Conflict of Interest: None
|How to cite this article:|
Puri B. The evolution and future of combat casualty care. J Mar Med Soc 2017;19:1-3
| Introduction|| |
Lessons learned from the battlefields of history have laid the foundation of modern trauma protocols. To the misfortune of humankind, the lessons of war are ongoing and relentless. Wounds of war are often gruesome and the physiological insults are horrendous. Tactical situations often mandate war wound management in suboptimal, hostile, and hazardous environments where sterility is suspect and resources are at a premium. On the other hand, combatants are generally fit before the injury event and are free of preexisting serious systemic illnesses. Their management therefore exposes the medical fraternity to the limits of the envelope of physiological stresses and their restoration.
Casualty management starts at the site of wounding with self or buddy care. Evacuation is often possible only during temporary cessation of operations. Primary onsite care, therefore, involves homeostasis with pressure bandages and local hemostatic agents such as quick clot or tourniquets. Analgesia is usually self-administered and involves the use of opioids. Evacuation proceeds through the channels of field hospitals. The time for evacuation may therefore vary from a few hours to even days in hostile terrain.
For optimal results, we need to have laid down protocols for wound assessment and management at all levels. Standardization is critical. Competence at each level needs to be credentialed and ensured. Finally, audits of war time care and the results achieved help us to prepare for tomorrow.
| Hemorrhage and Hemorrhagic Shock|| |
Hemorrhage is the primary cause of death in the war wounded. Control of hemorrhage in the war wounded involves local measures such as hemostatic gauze, regional control in war wounds of the extremities by application of tourniquets, and systemic measures including the use of Tranexamic acid. The United States Joint Trauma System recommends the use of Tranexamic acid for life-threatening hemorrhage with risk of coagulopathy and in patients receiving >10 units of blood (massive transfusion). Primary management of bleeding war wounds is by pressure dressings or the so-called shell dressing, where sterile-medicated gauze is stuffed into wounds and retained in situ by a pressure bandage.
Chitosan-based local hemostatic agents may be necessary to achieve hemostasis. Although the local exothermic reactions of “Quick Clot” or their substitutes may result in additional tissue injury, these packs are part of the kit of Special Forces the world over. These packs help hemostasis while a wounded soldier awaits evacuation and definitive treatment.
Limb injuries with exsanguinating bleeds may necessitate the application of tourniquets. In the groin area, tourniquet application is possible by specially designed devices called functional tourniquets which are like hemostatic clamps.
| Concept of War Wound Care|| |
The concept of delayed primary closure evolved the management of war wounds. Many factors are considered while deciding the timing of definitive closer. Today, negative pressure wound therapy is initiated after primary wound debridement. The timing of surgical closure is conventionally decided considering 4Cs, i.e., color, consistency, contractility when stimulated, and the capacity to bleed when incised.
| Chest and Abdominal Trauma|| |
Chest injuries may be associated with massive hemorrhage due to major vessel damage. Evaluation by whole-body computed tomography (CT) results in improved outcomes. Focused abdominal sonography in trauma (FAST) is effective in the diagnosis of intra-abdominal bleeding. FAST has replaced diagnostic peritoneal lavage which was at one time the gold standard for the diagnosis of intraperitoneal hemorrhage. A positive FAST in the absence of hemodynamic instability should be followed by a contrast CT scan. Injuries to major abdominal vessels require open surgical repair, while smaller vessel injuries can often be managed by embolization. Contained subcapsular hemorrhages of liver, kidney or spleen can be observed under close monitoring.
| Damage Control Surgery|| |
Damage control surgery involves limited surgical procedures to arrest hemorrhage and limit peritoneal contamination. Packs are often used to achieve hemostasis, and abdominal closure is usually done using mesh which can be incised for repeated easy access. Damage control orthopedic surgery involves the use of external fixators. The decision to do definitive fixation early or to manage with damage control orthopedics (external fixators) is sometimes guided by serum lactate levels. A rising serum lactate level >2.5 mmol/L indicates moderately severe tissue hypoperfusion. These patients need physiological stabilization prior to definitive skeletal fixation, and a damage control approach to resuscitation and surgery is mandated.
| Orthopedic Trauma in the Military Setting|| |
Fractures of the pelvis or femur may lead to hemorrhagic shock. Bleeding may be from the bone edges or from ruptured vascular plexuses or vessels. Fracture pelvis may be difficult to diagnose with only subtle limb shortening, deformity, or local ecchymoses as the only signs. Contrast CT for head-to-pelvis evaluation is recommended for the evaluation of hypotensive trauma patients. Pelvic fractures require binders for battlefield stabilization. Later, external fixators  are used. Failure of pelvic stabilization to provide hemostasis may necessitate angiography and embolization of bleeding vessels.
Femur fractures should be stabilized by splints or bandages in the battle field and should undergo external fixation as early as possible. Early intramedullary nailing has been recommended.
| Fluids and Resuscitation|| |
Hemorrhagic shock results in impaired tissue perfusion. Overtly, aggressive fluid resuscitation is however hazardous as fresh bleeding may get provoked. Initial resuscitation is usually with crystalloids. The “lethal triad” which is the avoidable end point of exsanguinations includes coagulopathy, hypothermia, and acidosis. The use of noradrenalin improves blood pressure resuscitation, reducing the risk of fluid overload. Persistent systolic hypotension of <90 mmHg even after administration of vasoactive drug indicates an ongoing loss and surgical intervention for bleeding control.
| History and Evolution of Fluid Resuscitation|| |
During the Vietnam War, a 3:1 volume resuscitation strategy was followed. Large infusions of isotonic saline were shown to increase the incidence of hyperchloremic metabolic acidosis. Ringer's lactate was therefore the crystalloid of choice for battlefield resuscitation. Ringer's lactate is, however, hypotonic. An increased incidence of acute respiratory distress syndrome or of interstitial fluid accumulation in other regions including gut, muscles, or even the pericardial cavity  was also noted with resultant lung and gut injury. Colloids were suggested as a panacea. However, colloid infusions were also found to increase mortality.
Hypertonic solutions have the theoretical advantage of drawing fluid from the interstitial compartment into the circulating blood. Hypertonic saline (7.5%) either alone or in combination with dextran (6%) was touted as an ideal fluid for prehospital resuscitation. However, studies showed no survival benefit.
The Institute of Medicine (US Army) has recommended an initial bolus of 250 ml of hypertonic saline for battle casualties in shock. The Uniformed Services University of Health Sciences, identified triggers for resuscitation which include a systolic blood pressure of <80 mmHg and altered consciousness in the absence of head injury. They recommended a hypertonic saline bolus of 500 ml in the prehospital environment. Hypotensive resuscitation targeting mean arterial pressure of 40 mmHg has been shown to result in better outcomes.
| The Concept of Combat Intensive Care|| |
An evolved combat casualty management protocol has ensured that many grievously injured combatants reach tertiary-level care. These severely injured soldiers respond to massive physiological insults with a quantum of inflammatory and immune dysregulation rarely seen in civilian practice.
The management of these cases is optimally performed in an intensive care setting with continuous physiological and biochemical evaluations.
| Conclusion|| |
The management of combat casualties needs standardization of management protocols, of evacuation modalities, and integrated advanced intensive case with subspecialty backup. As the weapons of war evolve, the management of war wounds too needs to advance and keep pace.
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