The diagnosis of brain death remains a clinical challenge for intensive care unit physicians. Worldwide regulations in its diagnosis may differ, and the need of ancillary tests after a clinical examination is not uniform. Transcranial sonography is a noninvasive, bedside, and widely available technique that can be used in the diagnosis of the cerebral circulatory arrest that preceeds brain death. In this paper we review the general concepts, the technical requisites, the patterns of Doppler signal confirming cerebral circulatory arrest, the vessels to insonate, and the options in cases with poor acoustic window. Future research perspectives in the field of transcranial sonography are discussed as well.
The diagnosis of clinical death in many critically ill patients has evolved from a cardiopulmonary event to the development of brain death, which is characterized by the irreversible loss of brain function [
The diagnosis of brain death remains a clinical diagnosis and it can be usually declared when brainstem reflexes, motor responses, and respiratory drive are absent in patients with massive brain injuries [
Clarification of the etiology of coma, mainly by means of cranial computed tomography or magnetic resonance imaging in accordance to medical history review. Exclude potential causes of loss of brain stem function. For example, acute arterial hypotension, hypothermia, which may mimic complete and irreversible brain injury and therefore the body temperature should be above 32°C or 90°F, drug intoxication and acute and severe metabolic causes of coma (glucose, electrolytes, acid-base, or endocrine disturbances) have to be ruled out.
Includes the following [ Coma nonreactive to painful or verbal stimuli. Absence of brain stem reflexes. Abolished response to atropine [ Abolished response to the apnea test [
The confirmation of irreversibility varies depending on the national guidelines [
In Spain, the confirmatory tests can be divided into the following [ Those evaluating neuronal function: electroencephalography, evoked potentials. Those evaluating cerebral blood flow: cerebral angiography, digital substraction angiography, cerebral scintigraphy, transcranial sonography.
Other complementary techniques that have been recently shown to have promising results in the diagnosis of CCA [
In our environment, the most commonly used ancillary test is the electroencephalography. However, it cannot be used in patients who have received long-term sedatives, which is common in the ICU environment. In such cases, the most widely 24-hours/7-days available technique is transcranial sonography, which is usually performed by trained intensivists or neurologists.
The aim of this paper was to evaluate the application of transcranial sonography in the diagnosis of CCA. This includes the general concepts, the technical requisites, the patterns of Doppler signal confirming CCA, the vessels to insonate, and the options in cases with poor acoustic window.
Transcranial sonography is a noninvasive, safe, and bedside technique used to evaluate the circulation of the basal arteries in neurocritically ill patients [
To perform a transcranial sonography as a confirmatory test after a clinical diagnosis of brain death, some prerequisites are mandatory to avoid false results [ Evidence of brain injury. The exploration has to be performed by trained physicians with experience in the technique and familiar with the pathophysiology of brain death. The patient must be hemodynamically stable (systolic arterial pressure higher than 90–100 mmHg), avoiding hypothermia less than 32°C, must be normocapnic (pCO2 35–45 mmHg), and, in the absence of marked metabolic derangements, conditions that are
The system must be equipped with a 2 MHz pulsed-wave Doppler probe, using a sample volume lower than 10 mm [
The increase of ICP and subsequent decrease in CPP occurring in devastating brain injuries results in progressive changes in the Doppler spectra waveform [
In summary, the following Doppler sonographic patterns can be found: Increasing pulsatility of the Doppler waveform: it represents the increase in ICP. The existence of any anterograde diastolic flow does not correspond to a CCA pattern (Figure
Middle cerebral artery (M1) shows a minimal retrograde diastolic flow but the rest of the cycle shows a persistent diastolic flow that is not compatible with cerebral circulatory arrest. This was a 23-year-old male who suffered a traumatic brain injury developing refractory intracranial pressure that was treated with high-dose barbiturates. This pattern reflected high intracranial pressure (ICP 43 mmHg at the time of examination) with a pulsatility index of 2.14.
The pulsatility index (PI) is a common measure for describing the shape of signal waveforms. High PI is usually correlated with high intracranial pressure. It is calculated by the following formula:
PI = (peak systolic velocity − end diastolic velocity)/mean velocity (reference values in healthy subjects
The resistance index (RI) described by Pourcelot is a measure of peripheral flow resistance and is calculated by the following formula:
RI = (peak systolic velocity − end diastolic velocity)/peak velocity (reference values in healthy subjects Oscillating Flow: in this pattern, anterograde systolic flow is associated with a retrograde diastolic flow representing the reverberating movement of the blood in the cerebral vessels. When the anterograde and retrograde flow are nearly equal (the area under the envelope of the positive and negative deflection is nearly the same), the cerebral perfusion has ceased. This pattern corresponds to the angiographic appearance of CCA (Figure Systolic Spikes: when ICP equals systolic blood pressure, an early systolic spike pattern is usually observed in the Doppler spectra. These sharp systolic spikes must present a systolic peak less than 50 cm/sec and a duration less than 200 msec. Filters should be set at the lowest levels to avoid misinterpretations. This pattern corresponds to the diagnosis of CCA (Figure
Middle cerebral artery (M1) shows a typical pattern of oscillating flow. This was a 30-year-old female admitted due to severe meningitis with refractory intracranial pressure. This pattern was compatible with cerebral circulatory arrest.
Basilar artery shows a systolic spikes pattern. Note that peak intensity is lower than 50 cm/sec and peak width lower than 200 msec. This pattern was obtained by insonation through the foramen magnum at a depth of 82 mm in a 65-year-old female who presented a severe hemorrhagic stroke.
If the systolic spikes does not fill the above-mentioned criteria, CCA cannot be diagnosed (Figure Lack of Signal: the use of this pattern in the diagnosis of CCA is controversial, since the lack of acoustic signal can be secondary to ultrasonic transmission problems. To consider this pattern as a CCA one, an exploration showing flow in the vessels to insonate in the same conditions and by the same (experienced) operator has to be previously performed. This is a major limitation of transcranial sonography in the diagnosis of CCA, accounting for 10% of the cases.
Although diastolic flow is absent, basilar artery shows anterograde systolic spikes with peak intensity higher than 50 cm/sec and a wide peak width in a 54-year-old male with severe brain injury. The clinical examination showed a preserved response to the apnea test. Therefore, this pattern was not compatible with cerebral circulatory arrest.
Which vessels best correspond to the CCA has been a matter of debate. Both the extracranial and intracranial arteries have been studied. We recommend to insonate both middle cerebral arteries (MCAs) and the basilar artery (BA) [
Studies have evaluated internal carotid, middle cerebral, anterior cerebral, vertebral arteries, and basilar artery [
It is recommended to insonate both MCA and BA showing a CCA pattern (oscillating flow or systolic spikes) in two different explorations separated by 30 minutes. The rationale behind this recommendation relies on the assumption that transitory patterns compatible with CCA have been described in patients with rebleeding after subarachnoid hemorrhage, and after cardiac arrest, and, in the fact that, 30 minutes is sufficient to confirm the irreversibility of a CCA pattern [
The above-mentioned criteria are applicable in the presence of an intact skull [
In cases of difficult acoustic window, some authors have successfully used an ophthalmic approach to increase the number of conclusive studies. The transorbital imaging of the carotid siphon reflects the sonographic pattern of the anterior circulation [
In our experience, the use of ultrasound contrast agents (UCAs) to maximize the acoustic signal results in an increase of the number of conclusive studies. Since patients in whom we evaluate the existence of CCA have devastating injuries and low acoustic signal, the use of UCAs can be a relevant tool. With TCCS technology, we evaluated the benefit of using UCAs in 50 patients with CCA. A conclusive pattern of CCA was obtained in 90% of the patients in the TCCS exploration, which improved to 98% after using UCAs. This fact minimizes the need of a previous study in cases with poor acoustic window [
Transcranial sonography is a noninvasive, bedside, and widely available technique that can be used in the diagnosis of the CCA that preceeds brain death. A meta-analysis published in 2006 including the ten most relevant articles to date in a large population of 684 patients stated that its sensitivity was 89% and specificity
In addition, one must keep in mind that in cases with isolated brain stem damage with subsequent clinical brain death, the transcranial sonography examination can show maintained flow. The effect of severe hyperventilation can also result in modifications of the sonographic pattern due to cerebral vasoconstriction. These facts highlight the need of a rigorous protocol to rule out potential confounders.
In these authors’ opinion, transcranial sonography is a valid technique in the diagnosis of CCA when used by experienced operators. In addition, it is noninvasive, non-expensive, and can be performed bedside. The potential usefulness and the limitations of this technique have been discussed. Such limitations should be taken into account by physicians who perform and interpret the results.
In our opinion, different points remain to be elucidated in future research. Some of them are listed below. Can we use both TCD and TCCS ultrasound devices? If accepted that both MCAs and BA represent the mandatory vessels to insonate in patients with CCA, should we accept any alternative if those vessels cannot be obtained? In the systolic spikes pattern, a maximum systolic peak 50 cm/sec and duration of 200 msec is accepted. These recommendations are based on early studies [ Should we reject the lack of signal pattern with the increasing use of recently developed UCAs?
In summary, transcranial sonography constitutes a useful tool in the diagnosis of the cerebral circulatory arrest that preceeds brain death when physicians are familiar with strict diagnostic criteria and know the underlying pathophysiology. However, some points remain to be elucidated and, in these authors’ opinion, an update of the criteria stated by the consensus conference [