| Literature DB >> 24572006 |
Moriz Herzberg, Sandra Boy1, Thilo Hölscher, Michael Ertl, Markus Zimmermann, Karl-Peter Ittner, Josef Pemmerl, Hendrik Pels, Ulrich Bogdahn, Felix Schlachetzki.
Abstract
<span class="abstract_title">BACKGROUND: Transcranial color-coded sonography (TCCS) has proved to be a fast and reliable tool for the detection of <span class="Disease">middle cerebral artery (MCA) occlusions in a hospital setting. In this feasibility study on prehospital sonography, our aim was to investigate the accuracy of TCCS for neurovascular emergency diagnostics when performed in a prehospital setting using mobile ultrasound equipment as part of a neurological examination.Entities:
Year: 2014 PMID: 24572006 PMCID: PMC3996057 DOI: 10.1186/2036-7902-6-3
Source DB: PubMed Journal: Crit Ultrasound J ISSN: 2036-3176
Figure 1Map showing Regensburg and the surrounding area. Pins indicate sites of emergency calls. The Regensburg stroke mobile was housed at the stroke unit of the Department of Neurology, Bezirksklinikum Regensburg. The second stroke unit in Regensburg is located at the Department of Neurology, Krankenhaus Barmherzige Brüder Regensburg. Three telemedical stroke units within the TEMPiS network are located near Regensburg. Bar indicates 10 km (Google©).
Baseline characteristic of the study sample and examiner, location, and time to ultrasound
| All patients, | 232 |
| Patients included, | 102 |
| Sex (female/male) | 54/48 |
| Mean age (SD) | 76.8 (13.41) |
| Ultrasound examination time (mean, SD) | 5 min, 36 s (2 min,12 s) |
| Alarm-to-handover duration (mean, SD) | 65 min (25 min) |
| Contrast enhanced TCCS, | 41 |
| Distance to hospital, km | 10 (2–41) |
| Clinic admission, | |
| Stroke unit | 98 |
| Internal Medicine | 3 |
| Telemedicine Stroke unit | 1 |
| Examining physician | |
| Investigator 1 | 57 |
| Investigator 2 | 42 |
| Investigator 3 | 3 |
| Site of ultrasound investigation | |
| Patient's home | 51 (50%) |
| During transport in ambulance car | 43 (42%) |
| Private office practice | 4 (4%) |
| Public space | 2 (2%) |
| Senior citizen home | 2 (2%) |
TCCS, transcranial color-coded sonography; SD, standard deviation.
Initial working diagnostic
| Proved right ( | |
| Proved wrong ( | |
Preclinical working and discharge diagnostics
| Preclinical working diagnostic | Stroke | 69 | 15 | 84 |
| Stroke mimic | 4 | 14 | 18 | |
| Total | 73 | 29 | 102 | |
Sensitivity, specificity, positive predictive value, and negative predictive value
| Stroke vs. mimic | 94% (86 to 98) | 48% (29 to 67) | 82% (72 to 89) | 77% (52 to 93) |
SE, sensitivity; Sp, specificity; PPW, positive predictive value; NPW, negative predictive value.
Figure 2Left-sided subdural hematoma in an 80-year-old patient. (a) TCCS performed 30 min after onset of sensory aphasia shows a patent left MCA and the complete circle of Willis. (b) Cranial CT scan demonstrates a subdural hematoma (SDH), and (c) when viewed in retrospect, TCCS from the right side reveals the SDH in the contralateral hemisphere in B-mode (arrow). The patient's medical history included hypertension, diabetes, and a fall 2 days earlier.
Figure 3Images obtained in a 54-year-old patient with progressive left-sided paralysis due to a brain tumor. (a) TCCS revealed patent arteries, but the midline has shifted as seen in a non-optimal temporal bone window during CT. (1) ipsilateral and (2) contralateral posterior cerebral artery, (3) ipsilateral middle cerebral artery, and (4) ipsi- and contralateral anterior cerebral arteries (b) with shift to the contralateral side (arrow).
Final diagnosis and etiology at discharge
| TIA | Anterior circulation | Large artery atherosclerosis | 50 | ||
| Ischemic stroke | Posterior circulation | Cardioembolism | 24 | ||
| Hemorrhagic stroke | | | Small vessel occlusion | 13 | |
| Subdural hematoma | | | Stroke of other etiology | 4 | |
| No stroke | Stroke of undetermined etiology | 9 |
Figure 4Flow diagram showing the diagnostic imaging pathway used to diagnose ischemic stroke. It includes the diagnostic accuracy for M1 and ICA pathology. US, ultrasound of intra- and extracranial arteries; TCCS, transcranial color-coded sonography; M1, middle cerebral artery mainstem; ICA, internal carotid artery.
Diagnostic accuracy TCCS
| MCA mainstem and ICA | | | | |
| Preclinical TCCS | Occlusion | 11 | 1b | 12 |
| No occlusion | 3c | 71 | 74 | |
| Total | | 14 | 72 | 86 |
| MCA occlusion | | | | |
| Preclinical TCCS | Occlusion | 9 | 1b | 10 |
| No occlusion | 1d | 75 | 76 | |
| Total | 10 | 76 | 86 | |
aCTA, MRA, and CCT according to diagnostic pathway in stroke unite; bmassive intracerebral hemorrhage (ICH) described as distal MCA occlusion; cno ACA imaged and therefore 2 ICA occlusions or >80% stenosis with cross-filling missed; dcontrast through filter, and PCA described instead of MCA occlusion. CTA, computed tomography angiography; MRA, magnetic resonance angiography; CCT, cerebral computed tomography; ACA, anterior cerebral artery; ICA, internal carotid artery; MCA, middle cerebral artery; PCA, posterior cerebral artery.
Figure 5Distal MCA mainstem occlusion in a patient with global aphasia and right-sided hemiparesis. (a) Prehospital TCCS showed a resistance profile only at the origin of the left MCA, (b) whereas flow in the contralateral MCA was unremarkable. At the hospital, (c) a CT scan displayed a dense artery sign (arrow), and (d) a CTA showed occlusion of the MCA (arrow).
Figure 6Cross-filling suggestive of high-grade stenosis or occlusion of the ICA. Images obtained in a 73-year-old patient suffering from a TIA with a 5-min-long paresis of the right leg. During transport, the patient's high blood pressure and angina pectoris prompted a decision to admit him to the Department of Cardiology. The results of the TCCS changed that decision, however, and the patient was admitted to the Stroke Unit. Surgery was performed the following day. (a) TCCS reveals normal flow in the left MCA. (b) Flow in the left ACA was increased and retrograde, suggesting collateral filling through the anterior communicating artery. (c) CT-angiography shows patency of all intracranial arteries but lacks flow information. (d) DSA on the same day confirms a tight, high-grade stenosis at the origin of the left ICA.
Figure 7TCCS with Doppler spectrum revealing tachyarrhythmia with changing cardiac output volumes in a 50-year-old patient. The patient experienced 5 h of mild facial paralysis and weakness of the left arm. MRI confirmed a small cardioembolic right MCA infarction (not shown).