Cost-effectiveness of short-protocol emergency brain MRI after negative non-contrast CT for minor stroke detection

Ischemic stroke is one of the leading causes of severe disability and a major cause for cardiovascular mortality worldwide [1‐3]. The economic burden caused by ischemic strokes is very high, with about $65.5 billion spent on stroke in the USA in 2008 and an expected increase to about $184.1 billion in 2012 to 2030 [4]. Acute stroke care accounts for about one half of total direct medical costs within the first 12 months following ischemic stroke, and post-stroke care significantly contributes to the large expenses with rehabilitation services and facilities as key factors [4, 5]. In the acute setting, the length of stay in hospital is the most important cost driver [3]. Major strokes are preceded by minor strokes or transient ischemic attacks (TIA) in approximately 15–30%, with 40% of these precursor events occurring within 7 days and about 20% within 24 h before a major ischemic stroke [6, 7]. The definition of the term minor stroke is equivocal; however, it is commonly applied to ischemic strokes with a low National Institutes of Health Stroke Scale (NIHSS) score (≤ 1 or ≤ 3, respectively) [8]. Up to 65% of all acute ischemic events leading patients to seek medical attention are minor strokes or TIAs [9]. Urgent identification of these patients and immediate initiation of secondary prophylaxis lead to a risk reduction of 80 to 90% with regard to subsequent major strokes [9‐11]. Therefore, timely diagnosis of minor strokes is of foremost importance for rapid initiation of secondary prophylaxis and prevention of major stroke.

In the majority of emergency departments, computed tomography (CT) of the head is the primary imaging modality in neurological patients with suspected intracranial pathology. In severely neurologically impaired patients with high pretest probability of ischemic stroke, non-contrast CT may be complemented by CT angiography of the extra- and intracranial vessels and whole-brain CT perfusion imaging [12, 13]. In small ischemic lesions, non-contrast CT may remain negative, especially in the acute phase [14‐16]. However, the primary role of non-contrast CT in acute stroke is ruling out intracranial hemorrhage, as contraindication for intravenous thrombolytic therapy, not the detection of early ischemia signs. Depending on the overall clinical presentation, the likelihood of ischemic stroke, the absence of intracranial hemorrhage, and the time from symptom onset, the neurologist has three main options in these patients: (1) intravenous thrombolysis and admission to a stroke unit with further clinical workup (including electrocardiography and clinical risk assessment); (2) admission to a stroke unit, immediate initiation of secondary prophylaxis, and further clinical workup including MRI; (3) discharge from hospital after clinical risk assessment with or without secondary prophylaxis and referral to a neurological outpatient clinic for further clinical workup including MRI. However, time and monetary resources are known to limit the availability of MRI in the outpatient environment. In addition, a substantial percentage of neurological emergency patients present with mild and unspecific clinical symptoms and an overall low risk for ischemic stroke [17]. To detect small ischemic lesions and to increase diagnostic confidence in the emergency setting, it would be desirable to perform a short emergency MRI scan in this subset of selected patients. Vice versa, a negative MRI scan in the acute setting may support the diagnosis of stroke mimics and avoid unnecessary hospital admission and unnecessary secondary prophylaxis. In a previous study, short-protocol emergency MRI proved to be equivalent to standard-length protocol MRI with regard to image quality and lesion detection [18].

We hypothesized that short-protocol brain MRI is cost-effective for the detection of minor strokes in selected emergency patients with inconclusive neurological symptoms. The aim was to investigate the cost-effectiveness of supplemental short-protocol brain MRI after negative non-contrast CT in neurological emergency patients with mild and unspecific clinical symptoms.

This study did not require institutional review board approval. The analysis was based on a previously published prospective single-center diagnostic accuracy study validating a vendor-specific brain MRI short-protocol (5 standard sequences: sagittal T1-weighted gradient echo, axial T2-weighted turbo spin echo, axial T2-weighted turbo spin echo fluid attenuated inversion recovery, axial-diffusion weighted single-shot echo-planar imaging, axial T2*-weighted echo-planar imaging gradient echo; total acquisition time including localizer 04:33 min) against a standard-length protocol (equivalent 5 standard sequences, total acquisition time including localizer 15:25 min) for use in the neurological emergency setting [18]. Four hundred forty-nine patients with acute non-traumatic neurological symptoms presenting to the emergency department of a large university center were screened for study inclusion. Of these, 60 patients with suspected intracranial pathology and negative non-contrast head CT were included and subsequently scanned with the short-protocol MRI and the standard-length protocol, which served as reference standard. The short-protocol MRI proved to be equivalent to the standard-length protocol with regard to image quality and the detection of intracranial pathologies (sensitivity 0.939 [0.881–0.972]; specificity 1.000 [0.895–1.000]). Compared to CT, 93 additional intracranial lesions were detected by short-protocol MRI, of which 21 were acute minor strokes, leading to a change in patient management (initiation of acetyl-salicylic acid as secondary prophylaxis, admission to dedicated stroke unit) in 10% (6/59). A representative patient with CT-occult minor stroke detected by short-protocol MRI is shown in Fig. 1.

The present analysis reveals short-protocol MRI as a cost-effective strategy in emergency patients with suspected intracranial pathology and negative non-contrast head CT presenting with inconclusive neurological symptoms, being dominant even from an economic perspective. In this setting, the cost-savings due to a lower rate of major strokes and gains in effectiveness by application of preventive treatment may by far outweigh the additional costs of supplemental short-protocol MRI subsequent to negative head CT in the emergency situation.

Major strokes are preceded by minor strokes or transient ischemic attacks (TIA) in 15–30%, and about 40% of recurrent major strokes occur within 7 days and about 20% within 24 h after the initial minor stroke or TIA [6, 7, 30]. Urgent initiation of secondary prophylactic treatment after a minor stroke or TIA was demonstrated to prevent 80 to 90% of recurrent major strokes [9‐11]. The importance of a rapid treatment start has been demonstrated in detail in the EXPRESS study with a rate of recurrent stroke of 2.1% in patients receiving treatment within 1 day of the index event compared to a rate 10.3% in patients receiving treatment within 3 days of the index event [11]. These data clearly point to the pivotal role of an early detection of minor strokes, a current diagnostic gap that may be closed with MRI in the acute setting [14‐16].

Major stroke is of utmost clinical and economical importance, as it is associated with a very high economic burden for healthcare systems. About 40% of all stroke patients suffer moderate to severe disabilities and need special care; about 10% depend on long-term care facilities [4]. Acute stroke care accounts for about one half of total direct medical costs within the first 12 months following ischemic stroke, and post-stroke care significantly contributes to the large expenses. Rehabilitation services and facilities represent the most expensive factors [4, 5]. In the acute setting, the length of stay in hospital is the most important cost driver [35]. Minor stroke or TIA patients have a significantly shorter length of stay in hospital, less patients have to be admitted to the intensive care unit, and less patients are discharged to skilled nursing facilities with consecutive high expenses [3, 5].

In this context, our results indicate that additional investment in short-protocol MRI examinations in the emergency setting does not only increase the detection rate of minor strokes, but can be regarded as a highly cost-effective, dominant strategy by preventing major strokes with consecutively high costs. In our analysis, we found overall higher costs for patients without additional short-protocol MRI compared to patients undergoing additional MRI. Further, the cumulative calculated effectiveness in the CT-only group was lower compared to the additional short-protocol MRI group. In our deterministic sensitivity analysis, additional short-protocol MRI remained the dominant strategy in the ranges investigated, and even when assuming a relatively high cost of the ultrafast MRI of $500, it remained the cost-effective strategy. Transition probabilities, detection rates, and quality of life after a major stroke had a higher influence on the cost-effectiveness of additional short-protocol MRI than costs and sensitivity of MRI itself.

Our study adds to the field as it demonstrated the cost-effectiveness of supplemental short-protocol MRI subsequent to negative head CT in neurological emergency patients. In many related fields of research, the additional utilization of procedures and diagnostic tests has been shown to be cost-effective: Despite high costs in the acute setting, interventional treatment has been shown to be cost-effective in major stroke patients, even in patients with a limited overall life expectancy [26, 36]. Furthermore, a transition from a time window to a tissue window for stroke patients presenting with unknown onset time for endovascular treatment and intravenous thrombolysis has taken place [37‐39]. In this context, higher costs of MRI have been found to be cost-effective for major stroke patients with unknown onset time in order to allow treatment beyond traditional time windows in selected patients with salvageable brain tissue, thereby improving functional outcome after major stroke [40]. The cost-effectiveness of secondary prophylaxis, e.g., with antiplatelet therapy, has also been demonstrated in previous studies [41‐43].

In future studies and cost-effectiveness analyses, initial imaging with short-protocol or standard-length MRI instead of CT for selected patients should be investigated, as this may lead to an optimized diagnosis and treatment planning in patients with minor stroke symptoms.

Additional short-protocol emergency brain MRI after negative non-contrast head CT is a cost-effective strategy in selected neurological patients with mild and unspecific symptoms, resulting in lower costs and higher QUALYs.