Managing pelvic injuries continues to be a challenge for even the most experienced trauma surgeons. Pelvic fractures frequently result from a high-energy impact and are usually associated with multisystem injuries and catastrophic hemorrhage. As reported by Lunsjo et al. [17] and Agri et al. [21], most deaths related to pelvic fracture were caused by associated injuries, not the pelvic fracture itself. In these patients, the most common cause of death was severe traumatic brain injury [17, 21, 22]. Therefore, to specifically investigate the correlation of the fracture pattern and pelvic vascular injury severity with the outcome, patients with an AIS score higher than 2 for body regions other than the pelvis were excluded from the current study.
By dividing the patients into the s-PF and c-PF groups according to the fracture pattern, our results reveal that although the fracture complexity correlated well with the length of hospital stay, it had a nonsignificant correlation with the number of transfusions required. In an earlier study by Poole et al. [23], although the injury severity was correlated with the pelvic fracture severity, hospital outcomes were determined by associated injuries and not by the pelvic fracture. Furthermore, systems for the classification of pelvic injuries based on pelvic ring stability and their relevance to the association with transfusion requirements and mortality have been disputed in the literature. Osterhoff et al. [10] reported the value of the Tile and YB classification systems in predicting mortality, transfusion requirements and concomitant injuries. The number of transfusions significantly increased with increasing fracture pattern severity [10]. Similarly, Manson et al. [11] reported that patients with an unstable pelvic fracture based on the YB classification had higher transfusion requirements than those with a stable fracture. Nonetheless, one should note that in both Osterhoff’s and Manson’s studies, patients with severe pelvic fractures were more likely to have concomitant injuries that would lead to greater transfusion requirements. In contrast, an important difference between the current study and these two studies is that patients with significant concomitant injuries (AIS score >2) were not included in the current study. Therefore, in the current study, patient hemorrhage was mainly caused by pelvic injuries. Under these conditions, our results show that the fracture pattern (simple or complicated) was not correlated with the number of transfusions. Our results are in line with those reported by Sarin et al. [13]. They found that the pelvic fracture pattern (with or without major ligamentous disruption) did not consistently correlate with the need for urgent embolization. This suggests that the risk of exsanguination or the need for transfusion due to complicated pelvic fracture is probably similar to that due to simple pelvic fracture.
Vascular injuries caused by pelvic fracture are life-threatening because they often present as multifocal, noncompressible arterial and venous hemorrhages. Tien et al. [24] analyzed 558 consecutive trauma deaths at their institution and found that the most common preventable cause of death was hemorrhage from blunt pelvic injuries. An incorrect choice of where to transport these patients for further intervention could delay the time to definite hemorrhage control and increase the risk of mortality. In this regard, the assessment of potential severe vascular injury and timely hemorrhage control should be the highest priorities in the acute management of pelvic fracture [25].
Our data show that the severity of vascular injury was significantly correlated with patient outcomes. Compared to patients with mild vascular injuries, patients with severe vascular injuries were more likely to have unstable hemodynamics, a higher ISS, RTS and TRISS, a larger number of transfusions, and longer ICU and hospital stays. Consistent with our results, in a study that investigated the relationship of the hemorrhage volume with the outcome of pelvic fracture, Blackmore et al. [26] showed that subjects with large pelvic hemorrhage volumes were more likely to have pelvic arterial injuries and require a large number of transfusions. They also demonstrated a strong association between the pelvic hemorrhage volume and adverse clinical outcomes even though the pelvic fracture pattern was not taken into consideration in their study. Therefore, our results suggest that even for those patients with major injuries limited to the pelvic cavity, the severity of pelvic vascular injury appeared to be a much more significant factor than the pelvic fracture pattern in determining patient outcomes.
In addition, the above findings were still true even if only those patients with an ISS >=16 were considered. According to the current AIS scoring system for pelvic fractures, the AIS score is 4 for a moderate pelvic hematoma with an estimated blood loss <= 20% by volume, while it is 5 for a large hematoma with an estimated blood loss volume >= 20% [27]. That is, a pelvic injury with the same fracture pattern would be given a different AIS score according to the size of the hematoma or the volume of blood loss. Regardless of the pattern of pelvic fracture, our patients would have an AIS score >=4 as long as there was a significant amount of pelvic injury-related bleeding. Therefore, for patients with an ISS >=16 (which most likely indicated the presence of severe vascular injury rather than a complicated pelvic ring fracture), it was not surprising that the severity of vascular injury was more prognostic in predicting patient outcomes than the complexity of pelvic ring fracture.
In 2017, the World Society of Emergency Surgery (WSES) published its guidelines for the classification and management of pelvic trauma [16]. The WSES guidelines emphasize that the optimal treatment strategy should be determined by the hemodynamic status and associated injuries in addition to anatomical lesions. The first decisions are based mainly on the hemodynamic conditions rather than on the pelvic ring lesions. According to the WSES classification, minor pelvic injuries are defined as those with mechanically stable (LC type I, APC type I) and hemodynamically stable lesions, while moderate injuries comprise those with mechanically unstable fracture (LC type II-III, APC type II-III, VS and combined-type fractures) but hemodynamically stable lesions. In addition, severe pelvic injuries are defined as hemodynamically unstable lesions independent of mechanical status. While the main differences between minor and moderate injuries are the complexity of the fracture patterns, any fractures that are associated with unstable hemodynamics are categorized as severe injuries. Our results showed that patient outcomes were similar between the WSES mild and moderate types of pelvic injuries; however, patients with severe pelvic injuries had significantly worse outcomes than those with the other two types of injuries. Therefore, hemodynamic instability appears to be a more relevant factor than the complexity of the fracture pattern for patient outcome. These results suggest that the WSES classification, which takes both the fracture pattern and hemodynamic status into consideration, might be clinically more useful than the classic YB classification system.
There were no cases of mortality in our series. The most critical factor of this result was that interventional radiologists were available at our institution for 24 hours along with trauma surgeons. Most exsanguinating patients could be stabilized by transarterial embolization shortly after initial resuscitation whenever indicated [20, 25, 27, 28]. Another reason for the lack of mortality was that pelvic trauma patients with associated injuries that were confirmed to be the principal cause of death, such as severe brain injury, were not included in the current study [17, 21-23].
There are several limitations to this study. First, this was a single-center experience with relatively uniform practices based on standardized, acceptable guidelines. Second, given its retrospective nature, information bias and documentation errors in the trauma registry and medical records could have affected the accuracy of the data. Third, the findings of our study specifically came from a group of patients with pelvic trauma as the principle injury. As reported by Vaidya et al. [29], the leading cause of death from blunt pelvic trauma within 6 hours of injury was hemorrhage from multiple areas but rarely from the pelvic injury alone; moreover, that between 6 and 24 hours was severe head injury. Because patients with severe associated injuries were not a part of this cohort due to the design of the current study, outcome measures such as number of transfusions, length of stay and mortality should be interpreted with care when compared with the findings of other studies that included patients with multisystem trauma.