Management of Severe Traumatic Brain Injury in Pregnancy: A Body with Two Lives

Traumatic brain injury is the major contributing factor in non-obstetric mortality in developing countries. Approximately 20% of maternal mortality is directly correlated to injuries. Road traffic accidents and domestic violence are the most common nonlethal injuries that can threaten either the maternal or foetal life, and such events occur in one out of every 12 pregnancies. The treatment of severe traumatic brain injury in pregnancy requires a multidisciplinary team approach. The management of a pregnant trauma patient warrants consideration of several issues specific to pregnancy, such as the alterations in the maternal physiology and anatomy. In the case of maternal cardiac arrest with amniotic fluid embolism, intact neonatal survival is linked with the timing of caesarean section after maternal cardiac arrest. Moreover, the decision for perimortem caesarean section is clear after maternal cardiac arrest. The foetal survival rate is 67% if the operation is done before 15 min of cardiopulmonary compromise has occurred, and it drops to 40% at the duration range of 16–25 min. Whether minor or severe, traumatic brain injury during pregnancy is associated with unfavourable maternal outcomes. Injuries considered minor for the general population are not minor for pregnant women. Therefore, these patients should be intensively monitored, and multidisciplinary approaches should always be involved.


Introduction
Traumatic brain injury is the major contributing factor in non-obstetric mortality in developing countries. Approximately 20% of maternal mortality is directly correlated to such injuries. Road traffic accidents and domestic violence are the most common nonlethal injuries that can threaten either the maternal or foetal life, and such events occur in 1 out of every 12 pregnancies (1,2).
The physiological adaptations that occur as pregnancy progresses warrant several specific considerations in the management of severe traumatic brain injury in pregnant patients.
Aside from maternal injuries, foetal wellbeing and conditions that are unique to pregnancy or related to trauma (Rh immunisation, miscarriage, preterm labour, placental abruption and foetal demise), clinicians must keep in mind the possible radiation exposure and other teratogens (2). This review focusses on the evidence-based management of severe traumatic brain injury in pregnancy, from pre-hospital to post-operative care.

Pre-hospital Care
Paramedics should always presume that every female of reproductive age with significant injuries is pregnant until proven otherwise by a 152 tomography, should not be deferred or delayed due to concerns regarding foetal exposure to radiation (II-2B); and • Use of gadolinium-based contrast agents can be considered when the maternal benefit outweighs potential foetal risks (III-C).
Ionising radiation has the highest teratogenic potential during the period of organogenesis (5-10 weeks), with an increased risk of miscarriage before this period. After 10 weeks, radiation is more likely to produce growth restriction than teratogenic changes. Radiation exposure with a cumulative dose of > 5-10 rad (50-100 mGy) is associated with an increased risk of foetal malformation, usually limited to a gestational age < 18 weeks. There is a less than 6% chance of developing severe mental retardation, less than 3% chance of childhood cancer and approximately 15% chance of microcephaly with the total exposure radiation dose of 15 rad (4, 5), plain chest X-ray generally below 0.005 rad, pelvic X-ray below 0.4 rad and computed tomography of the head (1 cm slices) 0.05 rad (6). Magnetic resonance imaging and ultrasonography have not been associated with any adverse foetal effects. There is no evidence of teratogenic effects with gadolinium administration (3).

Management for the First and Second Trimesters
In any pregnancy before 13 weeks of gestation, the uterus is protected by the bony pelvis (3). Foetal loss in the first trimester is less likely the result of direct trauma (occurring less than 1% of the time), and instead, it is likely to be caused by uterine hypoperfusion resulting from maternal hypotension or death (7).
Any pregnancy is considered viable after 23 weeks of gestation in view of the low survival rate of the foetus and approximately 61% foetal loss in women with major injuries before this time. The standard guidelines for the management of traumatic brain injury can be applied to pregnant patients with appropriate modifications for the population (8). Prophylactic anti-epileptic therapy can be applied as a pre-emptive measure against intracranial hypertension-induced seizures. If neurosurgical intervention has been performed in early pregnancy (< 24 weeks), the decision about subsequent foetal management can be based on obstetric considerations (7). definite pregnancy test or ultrasound scan (III-C) (3). Oxygen supplementation is essential for both the mother and foetus for the prevention of hypoxia. Pregnancy should prompt positioning the patient in the left or right lateral decubitus position or manual displacement of the uterus to avoid compression of the vena cava, resulting in hypotension. Hypoxia and hypotension have detrimental effects on both lives, as these conditions are associated with approximately 50%-75% of mortalities. In general, treatment that is good for the mother is good for the foetus. For patients with a suspected spine fracture, the left lateral tilt position can be utilised.

In the Emergency Room
A complete obstetric and neurosurgical history is mandatory, as this will influence decision making. In cases of major trauma, the assessment, stabilisation and care of the pregnant women is the first priority; then, if the foetus is viable (≥ 23 weeks), foetal heart rate auscultation and foetal monitoring can be initiated, and an obstetrical consultation should be obtained as soon as is feasible (II-3B) (3).
In pregnant women with a viable foetus (≥ 23 weeks) and suspected uterine contractions, placental abruption or traumatic uterine rupture, urgent obstetrical consultation is recommended (II-3B) (3). In cases of vaginal bleeding at or after 23 weeks, speculum or digital vaginal examination should be deferred until placenta previa is excluded by a prior or current ultrasound scan (III-C) (3).
In view of the narrow range of blood pressure (BP) control, at 140/90 (mild preeclampsia) to 160/110 (severe pre-eclampsia), as well as avoidance of hypotension, BP should be reduced or controlled, aiming for a level of approximately 140/90 mm Hg. O-negative blood should be used if needed, in view of Rh immunisation.

Radiation Exposure
Diagnostic imaging in injured pregnant women is always delayed in view of reluctance to expose the foetus to ionising radiation. However, this discomfort should be avoided in critical decision making, and the risk of teratogenic potential should be well understood.
• Radiographic studies indicated for maternal evaluation, including abdominal computed section is best done before 5 min of maternal arrest, as this results in the highest foetal survival rate (15).

Post-operative Management
Continuing care in the intensive unit for pregnant women involves maintaining neurological and systemic homeostasis; in addition, sustaining the foetal viability should be undertaken (with or without surgery). Good analgesia support should be ensured to facilitate maternal mobility, as well as providing pain relief and avoiding undesirable haemodynamic compromises. Morphine, codeine and tramadol are safely applicable, with few side effects and the best pain control. It is important to avoid cyclooxygenase inhibitors, in view of their effects on platelet function and potential bleeding after intracranial surgery and the potential foetal complications that can arise (renal failure, necrotising enterocolitis and persistent foetal circulation after birth), especially after 32 weeks of gestation (16).
There is an increased risk of both deep venous thrombosis and pulmonary embolism due to alterations in clotting factors in pregnancy, as well as endothelial injury secondary to trauma and susceptibility to infection (17).
Pharmacological and nonpharmacological prophylaxis measurements should be encouraged, but the risk-benefit analysis of anti-coagulants should be considered after discussion with the neurosurgeon.

Obstetric Complications in Trauma
Management of suspected placental abruption should not be delayed pending confirmation by ultrasonography, as ultrasound is not a sensitive tool for its diagnosis (II-3D) (3). Pregnant patients with severe head injuries are at an increased risk of foetal death. The most common cause of foetal death in trauma patients is placental abruption (18).

Temperature
The foetal temperature parallels the maternal temperature, and both maternal hyperthermia and hypothermia may be associated with increased morbidity in the presence of increased intracranial pressure (19). Preservation of the normal body temperature of

Management for the Third Trimester
Based on the Brain Trauma Foundation 2016 guidelines, a variety of measures to control intracranial pressure can be administered, such as a slight head-up position, low tidal volumes during intermittent positive pressure ventilation and avoidance of vomiting (8). Application of mannitol in pregnant women should involve caution, as it slowly accumulates in the foetus, causing foetal hyperosmolality; this will lead to physiological changes, such as reduced foetal lung fluid production, reduced urinary blood flow and increased plasma sodium concentrations (9,10). However, in individual case reports, mannitol in doses of 0.25-0.5 mg/kg has been used and appears safe (11,12). Furosemide is an alternative, but it should also be used cautiously.

Neurosurgical Intervention
If the foetus is viable (> 24 weeks of gestation) at the time of the planned neurosurgery, a decision must also be made concerning whether delivery is appropriate. Neurosurgeons may face one of the following scenarios: − Caesarean delivery alone or followed by neurosurgery (simultaneous) • When the uterus interferes in traumarelated surgical interventions or • With foetal compromise in a viable foetus with a stable mother: placental abruption/uterine rupture (maternal mortality rate of up to 10% and nearly universal foetal mortality); and − Neurosurgery followed by caesarean/vaginal delivery • If cardiopulmonary resuscitation has been unsuccessful after 4 min or there is obvious impending or recent maternal death (III-B) (3).
The chance for maternal survival after cardiopulmonary arrest, as compared with that of women in the non-pregnant state, is only 30% (13). The decision to perform perimortem caesarean section must be made after maternal cardiac arrest, as 67% of foetuses survive if the operation is done before 15 min of cardiopulmonary compromise, but this proportion drops to 40% at 16-25 min (13,14). According to Katz et al., perimortem caesarean However, with the prone position, the placental perfusion may be increased, as reported in Nakai et al. (22).

Conclusion
Traumatic brain injury during pregnancy, whether minor or severe, is associated with unfavourable maternal outcomes. Injuries considered minor for the general population are not minor for pregnant women. Therefore, these patients should be intensively monitored, and multidisciplinary approaches should always be involved ( Figure 1, Table 1).
the pregnant patient undergoing neurosurgery may be achieved with a forced air warmer, and the body temperature can be monitored with a urinary bladder or oesophageal temperature probe (20).

Spine Trauma
Spine trauma in pregnancy should be treated in the same way as in non-pregnant women. Appropriate abdominal shielding for diagnostic imaging can be applied. The prone position for spinal surgery in pregnancy may cause difficulties with respect to foetal monitoring, emergent caesarean delivery and increased epidural venous bleeding (21 Overall management of the mother and baby in the case of severe traumatic brain injury in the mother, throughout the separate partum and post-partum periods, is shown. There is controversy regarding the treatment options for a viable baby. Duration of foetal monitoring following a traumatic event falls toward the ability to identify potential trauma-related foetal problems and premature labour or foetal distress. Uterine contraction is the most common traumata-related consequence, with secondary induction of increased intracranial pressure, with the potential for endangering both the mother and baby; necessary management should be instituted as soon as possible, without interfering with maternal resuscitation efforts