Abstract
Critically injured patients requiring surgical management often require complex multi-organ support in the intensive care unit. In order to achieve best possible patient outcomes a multidisciplinary approach is required between surgical and critical care specialists in order to optimise the care of the patients from arrival to discharge. Familiarity with the patient pathway, their injury severity, surgical management, and possible complications are paramount in the overall care of these patients. Trauma to the abdomen may result in solid organ, hollow viscus or major vascular injury, most commonly the liver, spleen, kidneys, pancreas, as well as the large and small bowel and vascular structures including major retroperitoneal vessels. These injures are graded in severity according to the American Association of Surgery for Trauma (AAST) which relates to both management strategies and outcomes. Damage control surgery (DCS) is now routine for battlefield abdominal trauma, and this philosophy has heavily influence current civilian practice. The five-stage sequence of DCS includes (i) patient selection, (ii) intra-operative, (iii) critical care, (iv) return to theatre; and (v) formal closure. This has been incorporated in to a broader philosophy of Damage Control Resuscitation. An understanding of the decision making and sequence of surgical management, as well as that of the abdominal compartment syndrome and open abdomen are important features of the management of the surgical patient in critical care, and are discussed in this chapter.
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Keywords
- Organ injury
- Damage control surgery
- Abdominal compartment syndrome
- Abdominal closure
- Selective non-operative management
How Should Intra Abdominal Injuries Be Classified?
Intra-abdominal injuries may be sustained either in isolation or as part of a polytraumatic pattern of injury. Since the abdomen contains both solid and hollow viscus organs, each must be considered individually and in concert with the rest during the diagnosis of and subsequent management of injuries. Major vascular structures within the abdomen may also be injured in blunt and penetrating trauma. Since appropriate management may include surgery, interventional radiology and/or selective non-operative management, accurate diagnosis is paramount, and may utilise scoring systems for risk stratification and guidance of treatment. Modern ultrasound and cross-sectional imaging techniques allow the anatomical delineation of injuries in order to aid this diagnostic and decision making process. Indeed, availability of radiological adjuncts such as Focussed Assessment with Sonography in Trauma (FAST) and Computed Tomography (CT) can improve outcomes [1], and prevent unnecessary surgery even following battlefield injury [2]. The former is useful in the overall assessment of patients and decision making, whereas the latter may enable delineation of anatomical injuries.
Solid Organ Injury
The most commonly injured solid organs include the liver, spleen, and kidneys [3]. Specific Organ Injury Scales (OIS) relating to each of these organs have been assigned by the American Association for the Surgery of Trauma (AAST) [4, 5]. These facilitate the reporting and comparison of management strategies and outcomes but do not directly relate to specific management of individual patients, which is more dictated by haemodynamic parameters and stability over time. These OIS are illustrated in Table 13.1 (Liver), Table 13.2 (Spleen), Table 13.3 (Kidney), and Table 13.4 (Pancreas). Blunt splenic trauma (even higher grades of injury) may be treated selectively by non-operative strategies [6]. Although this may be suitable for some penetrating splenic injuries, the vast majority are still managed surgically [7]. Both blunt [8, 9] and penetrating [10] hepatic injuries may also be managed non-operatively with the caveat that certain associated risk factors, such as other injuries, peritoneal signs, and high injury severity scores increase the risk of the requirement for surgery [8]. Kidney trauma is most commonly managed non-operatively, with the exception that Grade V injuries are likely to require surgery [11]. Pancreatic injury management may also be managed selectively non-operatively but this needs to tempered by the high incidence of associated duodenal and vascular injury and complications from major pancreatic duct disruption.
Hollow Viscus Injury
A high index of suspicion is warranted for hollow viscus injury following abdominal trauma, including following blunt trauma [12]. The presence of a solid organ injury is predictive of hollow viscus injury [13], and therefore it is important to consider all contents of the abdomen rather than the most obviously injured organ. Classification of small bowel and colonic injuries according to AAST [14] are illustrated in Table 13.5. Hollow viscus injury with peritoneal leakage of bowel contents following trauma must be treated surgically in order to prevent sepsis and multi-organ failure. Very early CT scan may show the solid organ injury but miss associated hollow viscus injury as radiological signs for this take time to develop (bowel thickening, changes in perfusion, associated fluid collection etc.). Therefore a high index of suspicion for associated hollow viscus injury in patients with solid organ injury managed non-operatively must be maintained and rescanning considered if there is any doubt.
Retroperitoneal Vascular Injury
Retroperitoneal trauma may cause vascular injury, bleeding, and formation of haematoma that may further injure the retroperitoneal anatomical structures. Such haematomas can be divided into three zones in terms of the anatomical relationships. The decision to manage retroperitoneal injuries with surgery or conservative treatment depends on the likely structures that may have been injured, and the mechanism of injury:
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Zone 1 (central and medial; may lead to pancreaticoduodenal injury and/or major abdominal vascular injury). If the mechanism of injury is penetrating, then Zone 1 injuries must be explored surgically due to risk of injury to the aorta, vena cava, coeliac trunk, and superior mesenteric artery. Blunt trauma may be managed conservatively, but with a high index of suspicion.
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Zone 2 (lateral/perinephric area; may cause injury to the colon and/or genitourinary system). Penetrating injuries to this zone should also be explored in order to check for injuries to the ipsilateral kidney, adrenal gland, ureter, and renal vasculature. It is important to note that even blunt trauma may cause secondary penetrating trauma from fractured ribs. Blunt trauma may safely be managed conservatively. However, if a Zone 2 haematoma is diagnosed during laparotomy, the surgeon must note whether it is expanding or pulsating, and explore if this is the case.
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Zone 3 (pelvic, usually due to pelvic fracture and/or ilio-femoral vascular injury). Blunt trauma to this zone requires an external fixation device to compress the haematoma. Selective angio-embolization of bleeding vessels may be required if the patient remains haemodynamically unstable. Surgical exploration is only indicated following penetrating injury.
What Is Damage Control Surgery?
The concept of damage control in naval warfare refers to the well-rehearsed, efficient and timely efforts of a crew to keep a damaged ship afloat in order to maintain mission integrity and return to port for more definitive repairs. Along similar lines, damage control surgery (DCS) is a surgical strategy to directly address the physiological stresses of major trauma without the need for definitive restoration of anatomy; to keep the injured soldier alive long enough—like the damaged ship—to return home for definitive ‘repairs’. The DCS operative strategy sacrifices the completeness of the immediate surgical repair in order to address the physiological consequences of the combined trauma of injury and subsequent surgery.
Major trauma is characterised by a sudden, severe anatomical insult leading to catastrophic haemorrhage and major imbalance of physiological parameters. Loss of blood volume and subsequent hypothermia stimulate widespread adrenergic vasoconstriction. Clotting factors are depleted, leading to coagulopathy and further bleeding. The resulting haemodynamic compromise and hypoperfusion of organs with tissue injury leads to anaerobic respiration of tissues and metabolic acidosis. This process has been called the ‘trauma triad’, ‘lethal triad’ or ‘triad of death’ of hypothermia, acidosis and coagulopathy [15–17]. It is this physiological cascade that must be mitigated in order for the casualty to remain alive long enough to achieve future definitive care.
Damage Control Versus Primary Surgery
Before the philosophy and practice of DCS, conventional wisdom dictated that a casualty would undergo initial resuscitative measures in the emergency department of a hospital, and when ‘stabilised’ would be transferred to the operating theatre for definitive repair of their injuries (i.e., primary surgery). The patient may then be transferred to the intensive care unit (ICU) post-operatively for further resuscitation and physiological monitoring.
Such a logical sequence would supposedly negate the requirement for a return to theatre – indeed in such a model the requirement for further surgery might be considered to be an adverse event or complication. The DCS philosophy is different to this traditional model in the respect that surgery is only one part of the overall resuscitation, and that restoration of physiology (rather than anatomy) is the priority. DCS is one part of the overall process of Damage Control Resuscitation (DCR) that focuses on early correction of physiological derangement [18–20]. The introduction of DCR has influenced to practice of DCS as aggressive physiological correction extends surgical options.
Damage Control Sequence
When the term damage control surgery was first coined in 1993 by Rotondo and Schwab, the authors first described a classical three-stage approach, which mainly concerned abdominal trauma [21, 22]. Although the general concepts of DCS have remained fairly consistent since this original description, its practice has now evolved, and can be considered in 5 distinct stages [23, 24]. These stages are (i) Patient selection, (ii) Intra-operative, (iii) Critical Care, (iv) Return to theatre; and (v) Formal closure.
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I.
Patient selection
Regardless of physiological and situational parameters used in decision-making, a timely and considered decision is important, and must involve accurate communication between surgical, critical care and anaesthetic teams. This may occur either pre-operatively (before the patient has arrived in the operating room), or within the first minutes of surgical intervention. One formalised approach has been described by Rotondo and Zonies [25], and uses the patient selection factors of conditions, complexes and critical factors (Table 13.6). Additionally some physiological criteria that may indicate that a DCS approach is indicated have been suggested as: Injury severity score >25, systolic blood pressure <70 mmHg, core temperature < 34 °C and pH <7.1.
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II.
Intra-operative stage
The start of the intra-operative stage should be as soon as possible, and the time of surgery should be carefully monitored and kept to a minimum. The surgical team should be mindful of the dynamic changes in the patient’s physiology (including acid-base status, coagulation, temperature, blood product requirements). The basic philosophy is that the minimum must be done to stop haemorrhage, limit contamination, and provide temporary closure or cover of abdominal contents before the patient is rapidly transferred to critical care. Active warming is important and a theatre temperature of 26 °C is normal practice [19].
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Haemorrhage/vascular control
Although the application of proximal pressure and haemostatic dressings are useful in the initial control of bleeding, only surgical control is considered definitive [26]. The first priority during this operative stage is therefore the control of bleeding. Haemorrhage control may be achieved by ligation, suture, or tamponade (by packing or balloon). Large vascular injuries may also be treated with temporary shunting in order to facilitate subsequent vascular repair in order to preserve a limb. Definitive vascular repair by grafting or anastomosis during this stage is not appropriate, but may be considered in the later stages.
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Limit contamination
Contamination control is often achieved by stapled or tape closure of the ends of the injured hollow viscus. Anastomoses and stomas are not usually fashioned in DCS. A thorough washout with copious normal saline is also performed to minimize contamination.
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Temporary closure
Pre-emptive strategies to prevent compartment syndromes such as fasciotomies and laparostomy are employed. Temporary closure or cover is established in order to protect the abdominal contents whilst the patient is moved to a critical care environment. There are various temporary closure techniques used, which are described later in this chapter.
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III.
Critical Care Stage
In the critical care environment attempts continue at correcting the physiological consequences of injury and its associated metabolic failure. These concepts are discussed at length in Chaps. 5, 6, 7 and 8. Early return to the operating theatre is indicated if there is obvious ongoing surgical bleeding or a compartment syndrome develops.
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IV.
Return to the operating theatre
This is dictated by improvement in the patient’s physiological status. The following indices are often used to guide re-operation; base deficit > −4 mmol/l, lactate < 2.5 mmol/l, core temperature >35 °C and an International Normalised Ratio < 1.25 [24]. Before the decision to return to the operating theatre is made, plans to assemble the appropriate surgical team must be put in place to ensure that the optimum repairs of the injuries are performed in the optimum surgical environment. This may require more than one surgical specialty, but with a clearly identified leader to orchestrate the procedures and take a global view of the patient’s condition. At this stage anastomoses are fashioned, stomas raised and vascular repairs performed. However, surgical judgment on restoring gastrointestinal continuity should be exercised and in particular the requirements for on going inotropic support.
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V.
Formal closure
This may not be possible at stage IV as there may still be significant oedema or clinical risk of developing a compartment syndrome (abdominal or extremity). Therefore a planned further operative phase for closing or covering the site is made. The balance of risks between leaving the abdomen open as a laparostomy or delayed closure will depend on the injuries sustained and the overall condition of the patient and their abdominal viscera. Component separation or mesh repair may be considered, and are discussed further later in this chapter [27]. If fascial closure has not been possible by day 10 it may be safer to allow the laparostomy to mature and plan a delayed closure many months later rather than risk making an inadvertent enterotomy to get closure earlier.
Vascular Damage Control
Major vascular injuries must be dealt with quickly and urgently in order to stop haemorrhage and potentially enable limb salvage, but cannot wait until transfer to vascular specialist units. Damage control techniques may be utilised during surgery that do not necessarily require vascular specialists to perform. Although most distal vascular injuries can be ligated, an injured proximal portion of an extremity vessel may threaten the viability of that limb. The damage control surgery technique of placing a temporary vascular shunt may make limb salvage possible, and has long-term limb preservation results similar to those where initial revascularisation was attempted [28]. This technique is relatively straightforward, quick, and does not necessarily require specialist vascular support. It enables the preservation of circulatory flow to the threatened limb so that subsequent definitive vascular reconstruction may be performed by an appropriately trained and skilled surgeon. This technique is performed by gaining proximal and distal control of the area of bleeding, followed by proximal and distal thrombectomy (using an appropriately sized Fogarty catheter). The temporary shunt is then placed into the vessel lumens creating a ‘bridging’ temporary pathway for circulatory flow. Where the injuries are so severe that this is technically impossible, or the limb is unsalvageable, amputation is indicated at a level at which viable and vascularised tissue may be preserved.
Military Experience
Damage control surgery is now in routine use for battlefield trauma. Its practice has recently been shown to reduce mortality and faecal diversion for abdominal injuries [29], and good limb salvage results following vascular injury [30]. In recent years the experiences of DCS from the deployed military has had influence on civilian practice [31, 32] but more investigational research is required to demonstrate true translatability. A Cochrane Review found no published or pending randomised evidence that compared DCS with immediate and definitive repair in patients with major abdominal trauma [33], and further evidence-informed consensus is required to address this uncertainty [34].
Which Patients Require Acute Operative Intervention Following Abdominal Trauma?
Before the advent of interventional radiology for trauma and detailed cross sectional imaging techniques such as computed tomography (CT), laparotomy was considered mandatory for penetrating trauma and serious blunt trauma with physiological compromise. This was associated with a risk of non-therapeutic laparotomy in some studies ranging from to 9–37 % [35], which can cause potentially preventable complications and morbidity. More recently, non-therapeutic laparotomy has been reported as low as 3.9 % even following battlefield injuries due to the sensitive and specific nature of comprehensive CT imaging and reporting [2]. The management of trauma patients can therefore be divided into (a) surgical; (b) selective non-operative management; and (c) interventional radiology.
Selective Non-operative Management
Selective non-operative management (SNOM) is a management strategy where patients are observed without surgery, by careful and regular examination and clinical assessment. It is preferable that the same examiner or team should regularly assess the patient to detect any deterioration in clinical status that would indicate intervention is required. Such an approach must be tailored to the individual patients’ needs on a case-by-case basis. Injuries that may be managed using SNOM include solid organ injuries such as splenic and hepatic lacerations. Indeed SNOM for splenic injury is used as a quality indicator for surgical units that treat children [36]. The subsequent requirement for surgery may increase with the AAST grading of the solid organ injuries, and therefore a higher index of suspicion is warranted the higher the injury grade. Even penetrating injuries to the abdomen do not necessarily require surgery, and can be managed by SNOM. The Eastern Association for the Surgery of Trauma recently published clinical practice guidelines, recommending that “A routine laparotomy is not indicated in hemodynamically stable patients with abdominal stab wounds without signs of peritonitis or diffuse abdominal tenderness” [37].
Interventional Radiology
Some solid organ injuries may be suitable for interventional radiological management rather than surgery. Selective angioembolisation following blunt trauma can reduce the non-therapeutic laparotomy rate, and can be used for injury grades IV and V [38]. Inter-disciplinary discussion between radiology and surgical specialists and appropriate imaging techniques are vital for the success of this approach.
Surgical Intervention
Despite advances in diagnostic techniques, there are still some injuries for which laparotomy is mandatory. Hollow viscus injury following trauma with leakage of abdominal contents may only be treated with surgical intervention. Uncontrolled haemorrhage and clinical deterioration are also indications for emergency surgery, and damage control surgery if deemed appropriate. Solid organ injuries which have deteriorated despite SNOM and/or interventional radiology may also require surgical intervention for definitive management.
What Is Abdominal Compartment Syndrome?
Abdominal compartment syndrome is a dangerous complication that may lead to organ failure, diaphragm splinting, compression of the inferior vena cava, and reduction of cardiac return.
Definition
Abdominal Compartment Syndrome (ACS) has been defined by the World Society of the Abdominal Compartment Syndrome (WSACS) as a sustained intra-abdominal pressure (>20 mmHg) with or without an abdominal perfusion pressure of <60 mmHg that is associated with new organ dysfunction or failure [39].
Diagnosis
Early diagnosis is important, since treatment is urgent. Intra-abdominal pressure is commonly monitored by measuring the intraluminal bladder pressure via urinary catheter. A small volume of water is instilled into the bladder, and the tubing is clamped. A manometer is attached proximal to the clamp, and the pressure reading is given as the number of centimetres above the symphysis pubis (units cmH2O) (Fig. 13.1). However, management decisions should be made on the clinical picture and not solely based on pressure measurements.
Pathophysiology
ACS can arise for three main reasons: (i) increase in size/volume of intra-abdominal organs; (ii) diminished abdominal wall compliance; and (iii) increase in intra-abdominal fluid through capillary leak or fluid resuscitation. The abdominal organs may increase in size and volume due to inflammation (such as liver dysfunction and acute pancreatitis [40]), ileus and distension, bowel obstruction, malignancy, intra-abdominal collection, or infection. The abdominal wall musculature can decrease in compliance due to the position of the patient (for example if prone), major abdominal wall burns, trauma, and surgical intervention. Fluid leakage into the abdominal cavity can occur during massive fluid resuscitation [41, 42], in particular crystalloid fluid resuscitation [43].
How Should Abdominal Compartment Syndrome Be Managed?
Prevention
The WSACS have recommended that intra-abdominal pressure should be monitored when there are any risk factors for intra-abdominal hypertension or ACS, and that the trans-bladder technique should be the gold standard [39]. Primary prevention of ACS is preferable to management once it arises. Laparostomy (i.e., leaving an open abdomen) following emergency laparotomy may be indicated if ACS is thought to be likely. Delayed closure may be performed once the oedema and fluid balance have been corrected sufficiently to allow closure.
Treatment
Once ACS is confirmed, urgent decompressive laparotomy is required in order to relieve the pressure [44], and this should be followed with temporary abdominal closure. This may become necessary if the intra-abdominal pressure remains 20–25 mmHg and is causing a deterioration of organ failure. Onward management should include a combination of careful fluid management (to decrease the overall fluid balance), and appropriate utilisation of vasoactive medications.
How Should Critically Injured Patients with Open Abdomens Be Managed?
The primary aims of the management of the open abdomen are to provide temporary cover until a time at which it is appropriate to perform formal closure. Closure should be achieved as soon as feasible (and without causing ACS), since it may lead to fluid and electrolyte imbalance, septic complications (e.g., abscess, systemic infection), formation of fistulae and adhesions, catabolic state, and systemic inflammatory response [45]. The management of the open abdomen therefore has three main priorities: (i) providing cover to the contents, to prevent injury (e.g., bowel) and preventing the introduction of contamination; (ii) control the intra-abdominal fluid volumes (i.e., from ascites and resuscitative fluid leakage); and (iii) to enable future wound closure by preventing the formation of adhesions and lateral recession of the abdominal musculature [46]. Concurrent attention should be paid to nutrition [44] and fluid maintenance to ensure the patient has appropriate nutritional supplementation via the best route, and electrolyte balance. Antibiotic coverage (both antibacterial and antifungal) should be considered in close collaboration with microbiology specialists.
Temporary Covering of the Open Abdomen
Before fascial closure is performed, the open abdomen requires temporary closure to minimise the complications listed above. Adequate temporary closure of the abdomen must take into account the fact that there will be considerable amounts of fluid accumulated in the abdomen, which requires either frequent dressings changes or a system that can adequately collect and drain the fluid. The simplest version of temporary closure may be in the form of simple packing, such as non-adherent wet gauze. Although such an approach may be suitable for severe sepsis, it is not commonly performed for trauma. Skin may be closed without closure of the fascia, but this also carries a high risk of dehiscence and loss of skin. More common techniques in usage include the Bogotoa bag, mesh, and vacuum assisted (negative pressure) drainage. The necessity of siting stomas and minimising potential contamination is an important consideration.
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(a)
Bogota bag (Fig. 13.2)
A large IV bag may be fashioned into a shape suitable for coverage of the abdominal defect, and sutured or stapled to the skin edges [47]. This can then be covered by antibiotic-covered dressings and drapes. The whole dressing may be replaced at the bedside without requirement for further trips to theatre.
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Mesh
Non-absorbable mesh may be loosely fixed by suture to fascia on either side of the abdominal defect. As the swelling reduces, the central portion of mesh can be excised and the two edges re-sutured, or the central portion can be plicated (Fig. 13.3). This process can be repeated until the point at which the fascial edges can be brought together for definitive closure.
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(c)
Negative pressure dressings (Fig. 13.4)
Negative pressure therapy has the advantage of being suitable for fluid drainage (reducing the risk of intra-abdominal sepsis), as well as promoting angiogenesis, tissue perfusion, granulation, and bringing the skin edges closer together [48]. This is the approach recommended by the WSACS for the management of open abdomens [39]. The most common negative pressure dressings are the VAC Abdominal Dressing and ABThera Systems. Both of these systems are designed with individual layers: first a layer to protect the viscera, then a sponge fashioned into the shape of the defect, which is then covered with an adhesive occlusive (airtight) dressing. A vacuum is then created by connecting the perforated centre of the dressing to a negative pressure system. Such systems may allow definitive closure to be delayed.
Definitive Closure of the Abdomen
Fascial closure must be tension-free in order to prevent increased abdominal pressure, dehiscence, and ventral herniation. If the fascial edges do not come together without tension, then the options for closure include: intentional ventral hernia, component separation, or utilisation of bridging mesh between the fascial edges. The exact timing and technique for definitive abdominal closure should be decided on a case-by-case basis depending on the clinical status of the patient in terms of their anatomical and physiological suitability for further surgery.
References
Huber-Wagner S, Lefering R, Qvick LM, Korner M, Kay MV, Pfeifer KJ, et al. Effect of whole-body CT during trauma resuscitation on survival: a retrospective, multicentre study. Lancet. 2009;373(9673):1455–61.
Smith IM, Naumann DN, Marsden ME, Ballard M, Bowley DM. Scanning and war: utility of FAST and CT in the assessment of battlefield abdominal trauma. Ann Surg. 2015;262(2):389–96.
Arumugam S, Al-Hassani A, El-Menyar A, Abdelrahman H, Parchani A, Peralta R, et al. Frequency, causes and pattern of abdominal trauma: a 4-year descriptive analysis. J Emerg Trauma Shock. 2015;8(4):193–8.
Moore EE, Cogbill TH, Jurkovich GJ, Shackford SR, Malangoni MA, Champion HR. Organ injury scaling: spleen and liver (1994 revision). J Trauma. 1995;38(3):323–4.
Moore EE, Shackford SR, Pachter HL, McAninch JW, Browner BD, Champion HR, et al. Organ injury scaling: spleen, liver, and kidney. J Trauma. 1989;29(12):1664–6.
Brilliantine A, Iacobellis F, Robustelli U, Villamaina E, Maglione F, Colletti O, et al. Non operative management of blunt splenic trauma: a prospective evaluation of a standardized treatment protocol. Eur J Trauma Emerg Surg. 2015. [Epub ahead of print] DOI 10.1007/s00068-015-0575-z.
Berg RJ, Inaba K, Okoye O, Pasley J, Teixeira PG, Esparza M, et al. The contemporary management of penetrating splenic injury. Injury. 2014;45(9):1394–400.
Boese CK, Hackl M, Muller LP, Ruchholtz S, Frink M, Lechler P. Nonoperative management of blunt hepatic trauma: a systematic review. J Trauma Acute Care Surg. 2015;79(4):654–60.
Stassen NA, Bhullar I, Cheng JD, Crandall M, Friese R, Guillamondegui O, et al. Nonoperative management of blunt hepatic injury: an Eastern Association for the Surgery of Trauma practice management guideline. J Trauma Acute Care Surg. 2012;73(5 Suppl 4):S288–93.
MacGoey P, Navarro A, Beckingham IJ, Cameron IC, Brooks AJ. Selective non-operative management of penetrating liver injuries at a UK tertiary referral centre. Ann R Coll Surg Engl. 2014;96(6):423–6.
McCombie SP, Thyer I, Corcoran NM, Rowling C, Dyer J, Le Roux A, et al. The conservative management of renal trauma: a literature review and practical clinical guideline from Australia and New Zealand. BJU Int. 2014;114 Suppl 1:13–21.
Watts DD, Fakhry SM. Incidence of hollow viscus injury in blunt trauma: an analysis from 275,557 trauma admissions from the East multi-institutional trial. J Trauma. 2003;54(2):289–94.
Swaid F, Peleg K, Alfici R, Matter I, Olsha O, Ashkenazi I, et al. Concomitant hollow viscus injuries in patients with blunt hepatic and splenic injuries: an analysis of a National Trauma Registry database. Injury. 2014;45(9):1409–12.
Moore EE, Cogbill TH, Malangoni MA, Jurkovich GJ, Champion HR, Gennarelli TA, et al. Organ injury scaling, II: pancreas, duodenum, small bowel, colon, and rectum. J Trauma. 1990;30(11):1427–9.
Mikhail J. The trauma triad of death: hypothermia, acidosis, and coagulopathy. AACN Clin Issues. 1999;10(1):85–94.
De Waele JJ, Vermassen FE. Coagulopathy, hypothermia and acidosis in trauma patients: the rationale for damage control surgery. Acta Chir Belg. 2002;102(5):313–6.
Mitra B, Tullio F, Cameron PA, Fitzgerald M. Trauma patients with the ‘triad of death’. Emerg Med J. 2012;29(8):622–5.
Lamb CM, MacGoey P, Navarro AP, Brooks AJ. Damage control surgery in the era of damage control resuscitation. Br J Anaesth. 2014;113(2):242–9.
Morrison JJ, Ross JD, Poon H, Midwinter MJ, Jansen JO. Intra-operative correction of acidosis, coagulopathy and hypothermia in combat casualties with severe haemorrhagic shock. Anaesthesia. 2013;68(8):846–50.
Midwinter MJ, Woolley T. Resuscitation and coagulation in the severely injured trauma patient. Philos Trans R Soc Lond B Biol Sci. 2011;366(1562):192–203.
Rotondo MF, Schwab CW, McGonigal MD, Phillips 3rd GR, Fruchterman TM, Kauder DR, et al. ‘Damage control’: an approach for improved survival in exsanguinating penetrating abdominal injury. J Trauma. 1993;35(3):375–82; discussion 382–3.
Waibel BH, Rotondo MM. Damage control surgery: it’s evolution over the last 20 years. Rev Col Bras Cir. 2012;39(4):314–21.
Moore EE, Burch JM, Franciose RJ, Offner PJ, Biffl WL. Staged physiologic restoration and damage control surgery. World J Surg. 1998;22(12):1184–90; discussion 1190–1.
Midwinter MJ. Damage control surgery in the era of damage control resuscitation. J R Army Med Corps. 2009;155(4):323–6.
Rotondo MF, Zonies DH. The damage control sequence and underlying logic. Surg Clin North Am. 1997;77(4):761–77.
Parker P. Consensus statement on decision making in junctional trauma care. J R Army Med Corps. 2011;157(3 Suppl 1):S293–5.
Sharrock AE, Barker T, Yuen HM, Rickard R, Tai N. Management and closure of the open abdomen after damage control laparotomy for trauma. A systematic review and meta-analysis. Injury. 2016;47:296–306.
Hornez E, Boddaert G, Ngabou UD, Aguir S, Baudoin Y, Mocellin N, et al. Temporary vascular shunt for damage control of extremity vascular injury: a toolbox for trauma surgeons. J Visc Surg. 2015;152(6):363–8.
Smith IM, Beech ZK, Lundy JB, Bowley DM. A prospective observational study of abdominal injury management in contemporary military operations: damage control laparotomy is associated with high survivability and low rates of fecal diversion. Ann Surg. 2015;261(4):765–73.
Dua A, Patel B, Kragh Jr JF, Holcomb JB, Fox CJ. Long-term follow-up and amputation-free survival in 497 casualties with combat-related vascular injuries and damage-control resuscitation. J Trauma Acute Care Surg. 2012;73(6):1517–24.
Haider AH, Piper LC, Zogg CK, Schneider EB, Orman JA, Butler FK, et al. Military-to-civilian translation of battlefield innovations in operative trauma care. Surgery. 2015;158(6):1686–95.
Blackbourne LH, Baer DG, Eastridge BJ, Renz EM, Chung KK, Dubose J, et al. Military medical revolution: deployed hospital and en route care. J Trauma Acute Care Surg. 2012;73(6 Suppl 5):S378–87.
Cirocchi R, Montedori A, Farinella E, Bonacini I, Tagliabue L, Abraha I. Damage control surgery for abdominal trauma. Cochrane Database Syst Rev. 2013;(3):CD007438.
Roberts DJ, Bobrovitz N, Zygun DA, Ball CG, Kirkpatrick AW, Faris PD, et al. Indications for use of damage control surgery and damage control interventions in civilian trauma patients: A scoping review. J Trauma Acute Care Surg. 2015;78(6):1187–96.
Ertekin C, Yanar H, Taviloglu K, Guloglu R, Alimoglu O. Unnecessary laparotomy by using physical examination and different diagnostic modalities for penetrating abdominal stab wounds. Emerg Med J. 2005;22(11):790–4.
Safavi A, Skarsgard ED, Rhee P, Zangbar B, Kulvatunyou N, Tang A, et al. Trauma center variation in the management of pediatric patients with blunt abdominal solid organ injury: a national trauma data bank analysis. J Pediatr Surg. 2016;51:499–502.
Como JJ, Bokhari F, Chiu WC, Duane TM, Holevar MR, Tandoh MA, et al. Practice management guidelines for selective nonoperative management of penetrating abdominal trauma. J Trauma. 2010;68(3):721–33.
Bhullar IS, Frykberg ER, Siragusa D, Chesire D, Paul J, Tepas 3rd JJ, et al. Selective angiographic embolization of blunt splenic traumatic injuries in adults decreases failure rate of nonoperative management. J Trauma Acute Care Surg. 2012;72(5):1127–34.
Kirkpatrick AW, Roberts DJ, De Waele J, Jaeschke R, Malbrain ML, De Keulenaer B, et al. Intra-abdominal hypertension and the abdominal compartment syndrome: updated consensus definitions and clinical practice guidelines from the World Society of the Abdominal Compartment Syndrome. Intensive Care Med. 2013;39(7):1190–206.
Reintam Blaser A, Parm P, Kitus R, Starkopf J. Risk factors for intra-abdominal hypertension in mechanically ventilated patients. Acta Anaesthesiol Scand. 2011;55(5):607–14.
Dalfino L, Tullo L, Donadio I, Malcangi V, Brienza N. Intra-abdominal hypertension and acute renal failure in critically ill patients. Intensive Care Med. 2008;34(4):707–13.
Madigan MC, Kemp CD, Johnson JC, Cotton BA. Secondary abdominal compartment syndrome after severe extremity injury: are early, aggressive fluid resuscitation strategies to blame? J Trauma. 2008;64(2):280–5.
Balogh Z, McKinley BA, Holcomb JB, Miller CC, Cocanour CS, Kozar RA, et al. Both primary and secondary abdominal compartment syndrome can be predicted early and are harbingers of multiple organ failure. J Trauma. 2003;54(5):848–59; discussion 859–61.
Diaz Jr JJ, Cullinane DC, Dutton WD, Jerome R, Bagdonas R, Bilaniuk JW, et al. The management of the open abdomen in trauma and emergency general surgery: part 1-damage control. J Trauma. 2010;68(6):1425–38.
Huang Q, Li J, Lau WY. Techniques for abdominal wall closure after damage control laparotomy: from temporary abdominal closure to early/delayed fascial closure-a review. Gastroenterol Res Pract. 2016;2016:2073260.
De Waele JJ, Kaplan M, Sugrue M, Sibaja P, Bjorck M. How to deal with an open abdomen? Anaesthesiol Intensive Ther. 2015;47(4):372–8.
Fernandez L, Norwood S, Roettger R, Wilkins 3rd HE. Temporary intravenous bag silo closure in severe abdominal trauma. J Trauma. 1996;40(2):258–60.
Moues CM, Heule F, Hovius SE. A review of topical negative pressure therapy in wound healing: sufficient evidence? Am J Surg. 2011;201(4):544–56.
Gavrilovska-Brzanov A, Nikolova Z, Jankulovski N, Sosolceva M, Taleska G, Mojsova-Mijovska M, et al. Evaluation of the effects of elevated intra-abdominal pressure on the respiratory mechanics in mechanically ventilated patients. Macedonian J Med Sci. 2013;6:261.
von Ruden C, Benninger E, Mayer D, Trentz O, Labler L, Bogota VAC. A newly modified temporary abdominal closure technique. Eur J Trauma Emerg Surg. 2008;34(6):582.
Correa JC, Mejia DA, Duque N, J MM, Uribe CM. Managing the open abdomen: negative pressure closure versus mesh-mediated fascial traction closure: a randomized trial. Hernia. 2016;20:221–9.
Pliakos I, Papavramidis TS, Mihalopoulos N, Koulouris H, Kesisoglou I, Sapalidis K, et al. Vacuum-assisted closure in severe abdominal sepsis with or without retention sutured sequential fascial closure: a clinical trial. Surgery. 2010;148(5):947–53.
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Naumann, D.N., Midwinter, M. (2016). General Surgical Problems in the Critically Injured Patient. In: Hutchings, S. (eds) Trauma and Combat Critical Care in Clinical Practice. In Clinical Practice. Springer, Cham. https://doi.org/10.1007/978-3-319-28758-4_13
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