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Evidence review for TIA imaging
Evidence review C
NICE Guideline, No. 128
National Guideline Centre (UK).
1. Brain imaging after transient ischaemic attack (TIA)
1.1. Review question: After TIA, what is the optimal brain imaging strategy?
1.2. Introduction
The diagnosis of TIA is difficult, especially for non-specialist clinicians because the symptoms have, by definition, resolved, and there is no perfect diagnostic test. Making a diagnosis of a TIA is important because a) people with suspected TIA can have a range of other conditions (e.g. tumours or intracerebral haemorrhage, so called ‘mimics’) and b) people with confirmed TIA are at high risk of future ischemic stroke. The goal of assessment of suspected TIA is to establish the diagnosis and reduce the potential for future strokes by starting preventive treatments. Brain imaging might be helpful in excluding alternative diagnoses, improving risk prediction, or guiding treatment, but its role remains controversial. Previous NICE guidance and an HTA12 advise that specialist assessment is necessary before making decisions regarding imaging in suspected TIA, and suggest that the role of MRI remains unproven. Variation across organisations suggests that previous recommendations have not been implemented appropriately and CT imaging is still being performed routinely (including prior to specialist assessment). Inappropriate radiation exposure from CT causes risk to the patient while the routine use of CT or MRI might be an inappropriate use of resources which offer no clinical benefit.
Computed tomography (CT) is insensitive to the small areas of acute ischaemia likely to underlie most TIA syndromes, while magnetic resonance imaging is very sensitive in detecting both acute ischaemia (in about 50% of patients) and haemorrhage of any age. Clinicians remain uncertain about the value of either CT or MRI in assessing suspected TIA. Since 2008 further evidence has emerged regarding the value of MRI in predicting the risk of future ischaemic events, including ischaemic strokes.6 The pattern of diffusion weighted imaging (DWI) lesions can also help in determining the likely mechanism of ischemic stroke or TIA. In light of these advances in knowledge about imaging technologies in TIA, an evidence review was required to investigate the best imaging strategy in patients presenting with suspected TIA.
1.3. PICO table
For full details see the review protocol in appendix A.
Table 1
PICO characteristics of review question.
1.4. Methods and process
This evidence review was developed using the methods and process described in Developing NICE guidelines: the manual.10 Methods specific to this review question are described in the review protocol in appendix A.
Declarations of interest were recorded according to NICE’s 2014 conflicts of interest policy upto March 2018, and NICE’s 2018 conflicts of interest policy from April 2018.
1.5. Clinical evidence
1.5.1. Included studies
No relevant clinical studies comparing MR DWI and CT or any combination in a randomised or observational test and treat study design were identified.
See also the study selection flow chart in appendix C.
1.5.2. Excluded studies
See the excluded studies list in appendix E.
An HTA12 was identified that looked at whether MR with DWI is cost-effective in stroke prevention compared with CT brain scanning in all patients with TIA or minor stroke. The relevant chapter for this evidence review was planned to be a systematic review and meta-analysis of sensitivity/specificity of imaging strategies. However, no studies reporting sensitivity/specificity were identified and so the report assessed the frequency of DWI visible lesions in people with TIA or minor stroke. This HTA was highlighted in the NICE surveillance report and also as a key paper when discussing the protocol with the committee, however it did not meet the protocol criteria for this question. The committee were particularly interested in diagnostic test and treat outcomes. That is what happens downstream after imaging in terms of observed stroke, mortality, functional outcome and changes decision making and clinical management, to allow comparison of imaging strategies.
1.6. Economic evidence
1.6.1. Included studies
No relevant health economic studies were included.
1.6.2. Excluded studies
One economic study relating to this review question was excluded.12
This was an HTA published in 2014 that aimed to assess the cost effectiveness of routine MRI, including DWI, compared to routine CT in patients with TIA and minor stroke using economic modelling. It used a UK NHS perspective and QALYs as the health outcome measure. The population analysed was broader than the guideline review question as it included minor stroke as well as TIA (clinically TIA by definition has symptom resolution [within 24hrs and typically around 10 minutes] and in minor stroke symptoms persist after 24hrs; radiologically minor stroke will be DWI positive but TIA may not be; management and outcomes may also vary; some data in the model varied between people with TIA and minor stroke such as proportion of people with haemorrhage). The interventions compared were relevant for the review although did not cover all the options considered relevant by the committee – for example selective use of CT scanning in those with a ‘red flag’ for an alternative diagnosis that CT could detect. The model was comprehensive and model inputs were informed by systematic reviews. However, it was excluded becausethe clinical evidence the model was based on did not meet the inclusion criteria for the clinical review for the guideline. Specifically, as discussed above, the committee agreed that for the guideline evidence review diagnostic test and treat studies which compare clinical outcomes between groups where different diagnostic strategies have been used in people with TIA were the most useful evidence to inform decision making but no such studies were identified.
This is listed in appendix E, with reasons for exclusion given. See also study selection flowchart in appendix D.
1.6.3. Unit costs
Table 2
UK costs of outpatient imaging.
1.7. Resource costs
The recommendation made by the committee based on this review (see section Error! R eference source not found.) that CT imaging is not offered unless there is diagnostic doubt may have a substantial impact on resources to the NHS in England. The committee agreed this recommendation will reduce costs through greatly reducing the population requiring CT imaging in emergency departments. Additional savings are likely to be made by improving the flow of people with TIA to the TIA clinic and in the timeliness of delivering secondary Stroke and transient ischaemic attack in over 16s: evidence review C FINAL (May 2019) Review protocols prevention, which reduces the risk of stroke. Further work is being carried out to quantify the potential resource impact in this area.
The committee has also made a recommendation based on this review (see section Error! R eference source not found.) that urgent MRI (including diffusion-weighted and blood sensitive sequences) to detect ischaemia, haemorrhage or alternative pathologies should be ‘considered’ following expert assessment in the TIA clinic. Unlike for stronger recommendations stating that interventions should be adopted, it is not possible to make a judgement about the potential resource impact to the NHS of recommendations regarding interventions that could be used, as uptake is too difficult to predict. The committee was not confident of the effect of this recommendation on MRI requests. They acknowledged that this recommendation may increase the number of MRI requests compared to current practice. However, they also noted that it was not necessarily the case as the decision to do an MRI will not generally be affected by the results of a previous CT scan. Tthe committee was confident that CT imaging will decrease and so expect that this may offset the potential increase in MRI requests. The committee was uncertain whether overall these recommendations will be cost saving.
1.8. Evidence statements
1.8.1. Clinical evidence statements
- No relevant published evidence was identified.
1.8.2. Health economic evidence statements
- No relevant economic evaluations were identified.
1.9. The committee’s discussion of the evidence
1.9.1. Interpreting the evidence
1.9.1.1. The outcomes that matter most
This review focused on the ‘optimal’ brain imaging strategy in terms of improvement in patient outcomes. Critical outcomes for this review were stroke and mortality. Important outcomes were identified as functional outcome (mRS), quality of life and change in diagnosis or clinical management.
This review examined diagnostic test and treat outcomes, as the committee were particularly interested in the downstream outcomes after imaging. This included stroke, mortality, functional outcome and changes in decision making and clinical management. The committee agreed that diagnostic accuracy outcomes were not the most important factor in deciding on a strategy and therefore these would not provide as useful an insight for making a practice recommendation.
No evidence was identified for this question.
1.9.1.2. The quality of the evidence
No relevant clinical studies comparing MR, DWI and CT alone or any combination in a test and treat study design were identified. Therefore, there was no evidence to directly answer the question of whether brain imaging (unenhanced CT or MRI) after suspected TIA affects either subsequent treatment or early risk of stroke, or whether brain imaging of all suspected TIA cases is appropriate or cost effective.
An HTA12 was identified that aimed to perform a systematic review and meta-analysis on the diagnostic accuracy of MR with DWI compared with CT brain scanning in all patients with TIA or minor stroke. However, this was excluded because it did not meet the protocol for this question. This was because no test-and-treat trials or studies that directly compared MR DWI with CT scanning were included.
1.9.1.3. Benefits and harms
In the absence of any evidence, the committee based discussions on clinical experience and knowledge. The committee agreed that CT is most useful when there is a clinical suspicion of finding an alternative diagnosis that CT could detect, and should not be applied routinely to all suspected TIA cases. If exclusion of intracerebral bleeding is a clinical priority, for example, for those on anticoagulants or with a known bleeding disorder, or other reasons to suspect intracerebral bleeding (subdural haematoma, convexity subarachnoid haemorrhage, or intracerebral haemorrhage), then an unenhanced CT head scan should be performed. CT scans are indicated in the presence of ‘red flag’ clinical (for example headache, anticoagulation, head injury, repetitive stereotyped events) which suggest that the cause may not be a TIA. The committee anticipates that in these cases, those presenting to the ED would have the CT scan performed in ED, but those who present to primary care should be urgently referred to secondary care where the scan would be done if appropriate.
The committee discussed that routine CT imaging is common in current practice and could waste resources, extend the length of stay in ED, and expose people to unnecessary radiation. Therefore, they made a strong recommendation that CT brain scanning should not be offered to people with a suspected TIA unless there is clinical suspicion of an alternative diagnosis that CT could detect.
The committee discussed the possible risks of not offering CT brain imaging to all people with a suspected TIA. They agreed that, in the absence of specific ‘red flag’ clinical indicators Stroke and transient ischaemic attack in over 16s: evidence review C FINAL (May 2019) Review protocols (for example, headache, anticoagulation) it is rare for a CT scan to reveal an alternative diagnosis requiring a different referral pathway, and therefore the numbers of referrals to TIA clinics should not increase greatly. The risk of missing a TIA diagnosis by not performing a CT scan is also low because the committee agreed that the best diagnosis of TIA is by clinical assessment.
Additionally, based on the opinion and experience of the committee, urgent MRI, within 24 hours, should be considered after expert assessment in the TIA clinic to detect the presence and distribution of cerebral ischaemia, or alternative pathologies (TIA mimics, such as tumours, demyelinating disorders or convexity subarachnoid haemorrhage). MRI may also be needed to confirm the vascular territory of ischaemia before a decision is made to refer for a carotid endarterectomy, and may suggest alternative stroke mechanisms, such as cardiac embolism, large artery thrombo-embolism, haemodynamic compromise, or small vessel occlusion. MRI can also improve the assessment of future risk of stroke. However, the committee believed it was important to leave flexibility for clinicians in the TIA clinic to decide on the need for brain imaging based on the clinical scenario and agreed that MRI will not be required for all patients in a TIA clinic; therefore, the recommendation was to ‘consider’ MRI to allow for clinical discretion on an individual case basis. The potential harms for MRI are less than CT as there is no ionising radiation.
There was remaining uncertainty about whether urgent, routine MRI scanning versus standard care improves the outcomes of suspected TIA patients and so a priority research recommendation was framed in this area. The committee noted that this should be a cluster randomised test-and-treat trial comparing urgent routine MRI to usual care for all cases of suspected TIA within a TIA clinic.
1.9.2. Cost effectiveness and resource use
No cost effectiveness evidence was included for the optimal brain imaging strategy after TIA review.
In the absence of economic evidence, the committee considered the unit costs of MR and CT imaging. In the outpatient setting, non-contrast CT and MRI scans of one area currently cost £86 and £139, respectively. The committee noted that the unit costs of the imaging strategies are high and the population of those with suspected TIA is large. In addition, there is wide variation in current practice and issues surrounding access to imaging, particularly MRI.
In current practice, CT imaging is widely used in the ED in patients with suspected TIA to rule out other diagnoses, for example, intracerebral haemorrhage or a mass lesion. There is usually limited access to MRI in the ED. As CT imaging only identifies persistent deficits, people with TIA often have normal CT scans and are then sent to the TIA clinic where they may receive further imaging, usually MRI. Currently people with suspected TIA can experience delays in their transit through the ED, while awaiting CT imaging. The committee agreed that when a diagnosis of TIA is confidently suspected, CT imaging should not be routinely offered. The committee noted that CT imaging is only useful in specific cases when there is a clinical suspicion of alternative diagnoses which may be detected by CT, for example mass lesions or intracerebral haemorrhage.
The committee was confident this recommendation will reduce costs through greatly reducing the population requiring CT imaging in emergency departments, without negatively affecting patient outcomes. Furthermore, the committee expects that, by not routinely CT scanning patients with suspected TIA, there will be improvements in the flow of people with suspected TIA to the TIA clinic and in the timeliness of delivering secondary prevention, which is likely to improve patient outcomes and reduce downstream costs.
The committee agreed that the ‘gold standard’ diagnostic strategy for TIA is expert clinical assessment. The committee agreed that MRI is much more sensitive to acute cerebral ischaemia than CT imaging, with a sensitivity that decreases over time. MRI enables the detection and localisation of ischaemia, which allows clarification of the stroke mechanism and improved assessment of future risk. The committee agreed that the stroke physician/neurologist in the TIA clinic should dictate the need for imaging, noting that MRI will not be informative for all people with suspected TIA, such as those presenting late. The committee was not confident of the effect of this recommendation on MRI requests. They acknowledged that this recommendation may increase the number of MRI requests. However, they also noted that it was not necessarily the case as the decision to do an MRI will not generally be affected by the results of a previous CT scan. The committee was confident that CT imaging will decrease and so expect that this will offset any potential increase in MRI requests. The committee was uncertain whether overall these recommendations will be cost saving. They highlighted that they were not recommending routine early MRI for all instead of a CT as there was not evidence to support this and made a research recommendation in this area.
The committee noted that access to high quality MRI scanners is limited in some trusts and in particular in smaller hospitals. This could impact the implementation of the recommendation if more MRI scanning is required. The committee further discussed that undertaking an MRI scan takes more time than a CT of the head without contrast, although newer MRI scanners are faster. The number of MRI slots per day is currently limited, so there may be a need for dedicated MRI slots for people with suspected TIA.
In conclusion, no cost effectiveness evidence was identified for the optimal brain imaging strategy after TIA. The committee chose to recommend that CT scans are not offered to those with suspected TIA, unless there is clinical suspicion of a CT detectable alternative diagnosis. People with suspected TIA should undergo expert assessment, during which an MRI scan may be considered. The committee thought that recommending against the use of CT scans may offset any potential increase in costs due to the possible increase in use of MRI scans. The committee chose to recommend that further research be done which considers whether routine MRI screening for all those arriving in TIA clinics improves outcomes.
1.9.3. Other factors the committee took into account
The committee noted that imaging is performed routinely in some services, and sometimes involves both CT and MRI. This suggests that current NICE recommendations in CG68 are not being implemented appropriately.
The committee agreed that uncertainty about the need for brain scanning in this group remains, with variations between clinics in protocols for scanning people with suspected TIA. Often CT is used because of lack of access to MRI.
Regarding MRI, the committee acknowledged that timely access to MRI is not currently standard in TIA clinics. Delayed access reduces the utility of MR-DWI for detecting transient ischemic events as sensitivity reduces over time and, therefore, further reinforces the need for early expert assessment and timely access to MRI.
The committee noted that brain imaging is often performed simultaneously with vascular imaging of the intracerebral and extracranial arteries but did not assess this strategy as the question addressed was about brain imaging only.
References
- 1.
- Coutts SB, Modi J, Patel SK, Aram H, Demchuk AM, Goyal M et al. What causes disability after transient ischemic attack and minor stroke?: Results from the CT and MRI in the Triage of TIA and minor Cerebrovascular Events to Identify High Risk Patients (CATCH) Study. Stroke. 2012; 43(11):3018–22 [PubMed: 22984013]
- 2.
- Coutts SB, Modi J, Patel SK, Demchuk AM, Goyal M, Hill MD et al. CT/CT angiography and MRI findings predict recurrent stroke after transient ischemic attack and minor stroke: results of the prospective CATCH study. Stroke. 2012; 43(4):1013–7 [PubMed: 22302109]
- 3.
- Coutts SB, O’Reilly C, Hill MD, Steffenhagen N, Poppe AY, Boyko MJ et al. Computed tomography and computed tomography angiography findings predict functional impairment in patients with minor stroke and transient ischaemic attack. International Journal of Stroke. 2009; 4(6):448–53 [PubMed: 19930054]
- 4.
- Coutts SB, Simon JE, Eliasziw M, Sohn CH, Hill MD, Barber PA et al. Triaging transient ischemic attack and minor stroke patients using acute magnetic resonance imaging. Annals of Neurology. 2005; 57(6):848–54 [PubMed: 15929051]
- 5.
- Hefzy H, Neil E, Penstone P, Mahan M, Mitsias P, Silver B. The addition of MRI to CT based stroke and TIA evaluation does not impact one year outcomes. Open Neurology Journal. 2013; 7:17–22 [PMC free article: PMC3722541] [PubMed: 23894258]
- 6.
- Kiyohara T, Kamouchi M, Kumai Y, Ninomiya T, Hata J, Yoshimura S et al. ABCD3 and ABCD3-I scores are superior to ABCD2 score in the prediction of short- and long-term risks of stroke after transient ischemic attack. Stroke. 2014; 45(2):418–25 [PubMed: 24335223]
- 7.
- Kleinman JT, Mlynash M, Zaharchuk G, Ogdie AA, Straka M, Lansberg MG et al. Yield of CT perfusion for the evaluation of transient ischaemic attack. International Journal of Stroke. 2015; 10(A100):25–9 [PubMed: 23228203]
- 8.
- Moreau F, Asdaghi N, Modi J, Goyal M, Coutts SB. Magnetic resonance imaging versus computed tomography in transient ischemic attack and minor stroke: The more you see the more you know. Cerebrovascular Diseases Extra. 2013; 3(1):130–6 [PMC free article: PMC3884208] [PubMed: 24403904]
- 9.
- Moreau F, Modi J, Almekhlafi M, Bal S, Goyal M, Hill MD et al. Early magnetic resonance imaging in transient ischemic attack and minor stroke: do it or lose it. Stroke. 2013; 44(3):671–4 [PubMed: 23390118]
- 10.
- National Institute for Health and Care Excellence. Developing NICE guidelines: the manual. London. National Institute for Health and Care Excellence, 2014. Available from: http://www
.nice.org.uk /article/PMG20/chapter /1%20Introduction%20and%20overview [PubMed: 26677490] - 11.
- Souillard-Scemama R, Tisserand M, Calvet D, Jumadilova D, Lion S, Turc G et al. An update on brain imaging in transient ischemic attack. Journal of Neuroradiology. 2015; 42(1):3–11 [PubMed: 25649922]
- 12.
- Wardlaw J, Brazzelli M, Miranda H, Chappell F, McNamee P, Scotland G et al. An assessment of the cost-effectiveness of magnetic resonance, including diffusionweighted imaging, in patients with transient ischaemic attack and minor stroke: a systematic review, meta-analysis and economic evaluation. Health Technology Assessment. 2014; 18(27) [PMC free article: PMC4780985] [PubMed: 24791949]
Appendices
Appendix A. Review protocols
Appendix B. Literature search strategies
The literature searches for this review are detailed below and complied with the methodology outlined in Developing NICE guidelines: the manual 2014, updated 2017 https://www.nice.org.uk/guidance/pmg20/resources/developing-nice-guidelines-the-manual-pdf-72286708700869
For more detailed information, please see the Methodology Review.
B.1. Clinical search literature search strategy
Searches were constructed using a PICO framework where population (P) terms were combined with Intervention (I) and in some cases Comparison (C) terms. Outcomes (O) are rarely used in search strategies for interventions as these concepts may not be well described in title, abstract or indexes and therefore difficult to retrieve. Search filters were applied to the search where appropriate.
| Database | Dates searched | Search filter used |
|---|---|---|
| Medline (OVID) | 1946 – 19 February 2018 |
Exclusions Randomised controlled trials Systematic review studies Diagnostic tests studies |
| Embase (OVID) | 1974 – 19 February 2018 |
Exclusions Randomised controlled trials Systematic review studies Diagnostic tests studies |
| The Cochrane Library (Wiley) |
Cochrane Reviews to 2018 Issue 2 of 12 CENTRAL to 2018 Issue 1 of 12 DARE, and NHSEED to 2015 Issue 2 of 4 HTA to 2016 Issue 2 of 4 | None |
B.2. Health Economics literature search strategy
Health economic evidence was identified by conducting a broad search relating to the stroke population in NHS Economic Evaluation Database (NHS EED – this ceased to be updated after March 2015) and the Health Technology Assessment database (HTA) with no date restrictions. NHS EED and HTA databases are hosted by the Centre for Research and Dissemination (CRD). Additional searches were run on Medline and Embase for health economics studies.
Appendix C. Clinical evidence selection
Figure 1. Flow chart of clinical study selection for the review of brain imaging in TIA
Appendix D. Health economic evidence selection
Figure 2. Flow chart of health economic study selection for the guideline
Appendix E. Excluded studies
E.1. Excluded clinical studies
E.2. Excluded health economic studies
Appendix F. Research recommendation
F.1. Does early MRI brain scanning improve outcomes after suspected transient ischemic attack (TIA)?
Why this is important
Stroke is the single largest cause of adult disability and the third most common cause of death in the UK. People with TIA are at higher risk for a subsequent stroke. The diagnosis of TIA is made by specialist assessment and remains a clinical diagnosis based primarily on the clinical history of the TIA event. Secondary prevention strategies are based on this assessment and are vital to reduce the risk of future stroke. It is not known whether information provided by an early MRI brain scan – within 24-48 hours of the TIA event – improves on the clinical assessment, secondary prevention strategies or overall outcomes after TIA.
Criteria for selecting high-priority research recommendations
| PICO question |
Population: People aged over 16 years of age with suspected transient ischemic attack (TIA) Intervention(s): Routine MRI for all patients within 24-48 hours of TIA event. Comparison: Standard care based on clinical judgement and local protocols (i.e. no brain imaging, MRI at various time points or CT brain imaging if there is diagnostic doubt). Outcome(s): Stroke following TIA, mortality, recurrent vascular events, certainty of diagnosis, change in clinical management as a result of the MRI, improved elucidation of TIA mechanism, brain complications (bleeds), radiation exposure (from reduction in use of CT scans), quality of life |
|---|---|
| Importance to patients or the population |
People who have a TIA are a high risk group for future disabling stroke. If doing an MRI in all those with a suspected TIA had a favourable impact on the risk of stroke then there would be a positive impact with fewer people left disabled, and with impaired quality of life. If doing an MRI improved the understanding of the underlying cause of a TIA (for example by paroxysmal atrial fibrillation [PAF], cerebral amyloid angiopathy [CAA]) this would improve secondary prevention strategies and lead to fewer incident strokes. There may also be reduced radiation exposure as a consequence of fewer CT head scans required. |
| Relevance to NICE guidance | Currently there is a lack of evidence of the benefits of brain imaging with MRI following TIA. An answer to this question would mean access to a more robust evidence base and would enable an analysis of cost effectiveness. A future NICE committee could then answer the question – should everyone with a suspected TIA have an MRI brain scan within 24 hours of the event? |
| Relevance to the NHS | The type and extent of brain imaging for people with suspected TIA is highly variable within the NHS. Some suspected TIA patients have no brain imaging, some have CT brain scans and others MRI at variable time points following the TIA. New NICE guidance on this issue would really help stroke services and imaging departments plan for future brain imaging requirements for people with suspected TIA. If there was good evidence for MRI brain imaging after TIA then this would have an impact on service delivery within radiology departments. It may lead to far fewer CT head scans being performed in this cohort. If routine MRI for all patients reduces the number of recurrent vascular events, then the upfront costs of imaging may be recuperated through a reduction in downstream costs such as rehabilitiation and long term care. This could result in cost savings for the NHS. |
| National priorities | There will be a new ‘stroke strategic plan’ launched in 2018/19 by The Stroke Association and NHS England. TIA and stroke will be covered in this document and responsive services for people with suspected TIA will be a priority area. |
| Current evidence base | The evidence review in the clinical guideline found no test-and-treat trials directly comparing CT brain imaging with MR imaging after TIA and there was a lack of a good comprehensive evidence base for MR imaging after TIA. There was also a lack of studies on cost effectiveness of brain imaging after suspected TIA. |
| Equality | Not relevant to this question. All groups would be considered in the research. |
| Study design |
The most appropriate design would be a cluster (wedge) randomised test-and-treat trial design where people with suspected TIA are randomised in specific clusters to MRI at different early time points following the initial event or to standard care. Cluster randomisation is the most appropriate and practical design because it will allow each TIA service to operate under a single protocol at a given time. It would not be feasible for clinicians to randomise each case to MRI or control within one TIA service. Within a proposed intervention group (i.e. those having MRI) there would be a treatment algorithm for participating clinicians depending on the MRI findings. Treatment decisions and outcomes could then be analysed in the MRI and standard care (no MRI) clusters. |
| Feasibility |
Most stroke services have daily TIA clinics seeing 900 or more suspected TIAs per year. The cost of an additional MRI scan is about £250. Service support costs should be low as there are daily clinics in most services from which the study could be run. Access of additional cases to MRI scanners will be the main issue for participating centres. As the stroke clinical research network is already established it is likely many centres would want to participate in such a study and utilise their research nurses to help recruitment. |
| Other comments | |
| Importance |
|
FINAL
Intervention evidence review
This evidence review was developed by the National Guideline Centre
Disclaimer: The recommendations in this guideline represent the view of NICE, arrived at after careful consideration of the evidence available. When exercising their judgement, professionals are expected to take this guideline fully into account, alongside the individual needs, preferences and values of their patients or service users. The recommendations in this guideline are not mandatory and the guideline does not override the responsibility of healthcare professionals to make decisions appropriate to the circumstances of the individual patient, in consultation with the patient and/or their carer or guardian.
Local commissioners and/or providers have a responsibility to enable the guideline to be applied when individual health professionals and their patients or service users wish to use it. They should do so in the context of local and national priorities for funding and developing services, and in light of their duties to have due regard to the need to eliminate unlawful discrimination, to advance equality of opportunity and to reduce health inequalities. Nothing in this guideline should be interpreted in a way that would be inconsistent with compliance with those duties.
NICE guidelines cover health and care in England. Decisions on how they apply in other UK countries are made by ministers in the Welsh Government, Scottish Government, and Northern Ireland Executive. All NICE guidance is subject to regular review and may be updated or withdrawn.
- Review An assessment of the cost-effectiveness of magnetic resonance, including diffusion-weighted imaging, in patients with transient ischaemic attack and minor stroke: a systematic review, meta-analysis and economic evaluation.[Health Technol Assess. 2014]Review An assessment of the cost-effectiveness of magnetic resonance, including diffusion-weighted imaging, in patients with transient ischaemic attack and minor stroke: a systematic review, meta-analysis and economic evaluation.Wardlaw J, Brazzelli M, Miranda H, Chappell F, McNamee P, Scotland G, Quayyum Z, Martin D, Shuler K, Sandercock P, et al. Health Technol Assess. 2014 Apr; 18(27):1-368, v-vi.
- Diffusion-weighted imaging and diagnosis of transient ischemic attack.[Ann Neurol. 2014]Diffusion-weighted imaging and diagnosis of transient ischemic attack.Brazzelli M, Chappell FM, Miranda H, Shuler K, Dennis M, Sandercock PA, Muir K, Wardlaw JM. Ann Neurol. 2014 Jan; 75(1):67-76. Epub 2014 Jan 2.
- Magnetic Resonance Imaging versus Computed Tomography in Transient Ischemic Attack and Minor Stroke: The More Υou See the More You Know.[Cerebrovasc Dis Extra. 2013]Magnetic Resonance Imaging versus Computed Tomography in Transient Ischemic Attack and Minor Stroke: The More Υou See the More You Know.Moreau F, Asdaghi N, Modi J, Goyal M, Coutts SB. Cerebrovasc Dis Extra. 2013; 3(1):130-6. Epub 2013 Oct 8.
- Yield of combined perfusion and diffusion MR imaging in hemispheric TIA.[Neurology. 2009]Yield of combined perfusion and diffusion MR imaging in hemispheric TIA.Mlynash M, Olivot JM, Tong DC, Lansberg MG, Eyngorn I, Kemp S, Moseley ME, Albers GW. Neurology. 2009 Mar 31; 72(13):1127-33. Epub 2008 Dec 17.
- Review Magnetic resonance imaging versus computed tomography for detection of acute vascular lesions in patients presenting with stroke symptoms.[Cochrane Database Syst Rev. 2009]Review Magnetic resonance imaging versus computed tomography for detection of acute vascular lesions in patients presenting with stroke symptoms.Brazzelli M, Sandercock PA, Chappell FM, Celani MG, Righetti E, Arestis N, Wardlaw JM, Deeks JJ. Cochrane Database Syst Rev. 2009 Oct 7; (4):CD007424. Epub 2009 Oct 7.
- Evidence review for TIA imagingEvidence review for TIA imaging
- CCA tRNA nucleotidyltransferase 1, mitochondrial [Rattus norvegicus]CCA tRNA nucleotidyltransferase 1, mitochondrial [Rattus norvegicus]gi|66730382|ref|NP_001019432.1|Protein
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