Abstract
Purpose of Review
The purpose of the review is to examine recent evidence on the effects of intravenous thrombolysis and identify the remaining uncertainties.
Recent Findings
We review the results of two large trials (the third International Stroke Trial (IST-3) and The Enhanced Control of Hypertension and Thrombolysis Stroke Study (ENCHANTED)) and the publications from the individual patient data analyses of the trials of alteplase conducted by the Stroke Thrombolysis Trialists Collaboration.
Summary
Despite about a 2% risk of fatal intracerebral haemorrhage, on average, adult patients of all ages treated with 0.9 mg/kg alteplase within 4.5 h will have better long-term functional outcome. The use of a lower dose of alteplase (0.6 mg/kg) is associated with a lower risk of haemorrhage but its effect on functional outcome has not been proven to be non-inferior to standard dose therapy. Some clinicians feel confident to treat selected patients who present beyond 4.5 h or have unknown time of onset, but many also agree that the current trials and other research is needed to reliably define the optimum imaging methods and treatment eligibility criteria.
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Introduction
The majority of acute ischaemic strokes are the result of the occlusion of a cerebral artery, though the nature of the arterial obstruction can be very variable. [1] Commonly, large cerebral vessels are occluded by emboli (consisting of thrombus or other material) which reach the cerebral circulation from the chambers of the heart or great vessels while smaller vessels may be occluded by intrinsic vessel wall disease (such as lipohyalinosis, arteritis or other pathologies). As a treatment for acute ischaemic stroke, intravenous administration of fibrinolytic drugs is targeted chiefly on large vessel occlusion and aims to promote lysis of any emboli that contain fibrin. Clot lysis leads to reperfusion of ischaemic brain and should improve the chance of stroke recovery, but this benefit may be negated by an increased risk of intracerebral haemorrhage. We review recent evidence on the factors that influence the balance of benefits and harms of this important treatment.
Recent Evidence from Large Randomised Controlled Trials
The publication of the results of third International Stroke Trial (IST-3), the largest ever trial of intravenous (iv) thrombolysis with alteplase (0.9 mg/kg), with 3035 patients, doubled the world evidence base on iv alteplase. [2] The study had two unique features; it included a wider range of patients than previous studies, chiefly patients aged over 80 years (n = 1617) and followed them for up to 3 years (previous studies followed-up for just 3 months). [3, 4•] These data were then included in the individual patient data meta-analysis of the nine major trials of alteplase conducted by the Stroke Thrombolysis Trialists Collaboration (including 6756 patients) [5••]. This review concluded: ‘Irrespective of age or stroke severity, and despite an increased risk of fatal intracranial haemorrhage during the first few days after treatment, alteplase significantly improves the overall odds of a good stroke outcome when delivered within 4·5 h of stroke onset, with earlier treatment associated with bigger proportional benefits’. [5••]
The Need to Remove the Upper Age Limit for Treatment
The STTC data [5••] prompted the UK drug regulatory agency to suggest that there was a case for the 80-year upper age limit for treatment specified in the EU approval for alteplase to be reconsidered. [6] We strongly support this view, so the product licence, the summary of product characteristics and treatment guidelines should all be aligned to permit treatment of people aged over 80 years.
What Factors Do and Do Not Influence Risk of Intracerebral Bleeding?
Age and Time to Treatment
See Table 1. The new data clearly show that neither increasing time to treatment nor increasing age have a significant influence on the relative risk of intracerebral bleeding [5••, 7••]
Stroke Severity
By contrast, baseline stroke severity has a substantial effect; the absolute risk of fatal intracranial bleeding is lowest in mild stroke and highest in more severe stroke [7••] (Table 1).
Antiplatelet Therapy
Patients who receive antiplatelet drugs in the 48 h before their stroke onset have a higher risk of intracerebral bleeding, but have the same likelihood of a good functional recovery as those who do not. [8] By contrast, the co-administration of aspirin with the thrombolytic causes a sufficient increase in bleeding to negate any benefit on functional outcome. [9] The Enhanced Control of Hypertension and Thrombolysis Stroke Study (ENCHANTED) trial also suggested that patients already receiving dual antiplatelet therapy might receive greater net benefit with lower dose (0.6 mg/kg) alteplase.
Absolute Benefit from iv Thrombolysis Depends on Baseline Stroke Severity
Figure 1 shows the expected effect of thrombolysis in people with different baseline levels of stroke severity, ranging from mild (National Institutes of Health Stroke Scale (NIHSS ≤5) to very severe (NIHSS >22)). When making the decision about whether to treat or not, it is the absolute risks of fatal bleeding and of a good outcome that matter the most. People with mild stroke will make a good recovery, even without thrombolysis (small absolute benefit), while in severe stroke, the proportion of patients becoming independent in activities of daily living is small and not greatly influenced by treatment (small absolute benefit). However, on average, for many patients with a non-trivial stroke, thrombolysis can be expected to ‘shift’ treated patients of at least moderate severity towards a lesser degree of neurological impairment and disability than those not treated. Even though iv thrombolysis is of net benefit, it is not a cure-all. For example, of patients with a moderate to severe stroke (NIHSS 11–15) treated with iv thrombolysis, one would expect 39% to be alive and independent, but 61% would be expected to die or be dependent on others in activities of daily living. Such patients, who despite thrombolytic therapy are not expected to make a full recovery, may then be candidates for endovascular therapy (e.g. mechanical clot retrieval with a stent retriever device). [10] In our view, the priority is to ensure all patients with non-trivial strokes are considered for iv thrombolysis and all eligible patients treated as promptly as possible. There is debate as to whether or not it is necessary to give iv thrombolysis before endovascular treatment (we think it is), but ongoing trials such as SWIFT DIRECT will help to answer the question.
Controversies About Patient Selection
Mild Stroke
Patients with baseline NIHSS can be expected to do well without treatment; however, if the stroke causes a deficit such as isolated hemianopia or isolated aphasia, the NIHSS will be low, and the person’s quality of life may be very adversely affected. Yet, treatment plausibly carries a 1% risk of fatal intracranial bleeding, and hence the discussions with the patient and the family to weigh up potential benefits and harms may be very difficult because of the uncertainties. As a result, two trials comparing thrombolysis with control in patients with mild stroke are ongoing to resolve the uncertainty, PRISMS and TEMPO-2 (Table 2).
Severe Stroke
Some individuals with severe stroke may be prepared to accept a high (4%, or 1 in 25) immediate risk of fatal haemorrhage from treatment if their prognosis is poor (the person has ‘nothing to lose’), whereas for others, that level of risk may be unacceptably high. Better clinical decision aids are needed to support clinicians and patients in dealing with the difficult discussions that can arise in these circumstances. [7••]
Choice of Imaging Modality for Routine Cases
Facilities and local practice in the use of imaging to select patients for reperfusion therapy varies widely around the world. [11] For routine cases of stroke, where the time of onset is known reliably and treatment can be given within 4.5 h, we have a strong personal preference for rapid non-contrast CT as the imaging method of first choice to exclude haemorrhage, and if the stroke is moderate to severe, and endovascular therapy is rapidly available locally, CT angiography (CTA) is in addition. Demchuk et al. argue that CTA should become the minimum standard of care in acute disabling ischaemic stroke. [12]
Imaging for Endovascular Therapy, Late-Presenting (>4.5 h), Wake-up and Unknown Time of Onset Stroke
This is a controversial topic; criteria vary enormously and only 1% meet a common set of criteria. [13] In well-resourced centres where multimodal MR scanning is available, some experts feel confident to select cases for treatment on the basis of advanced imaging findings. However, there is no consensus on precisely what the imaging selection parameters for treatment should be and there is no ‘clear winner’. Current trials aim to better define the criteria for patient selection and given the limited availability of multimodal MR in some sites, the TWIST trial is evaluating the use of CT and CT angiography in wake-up stroke (Table 2). The DEFUSE 3 trial of endovascular therapy versus control also permits the use of either CT or MR perfusion and angiography for case selection. [14] When CTA and MRA are not available, transcranial Doppler ultrasound, in experienced hands gives a good indication of vessel patency [15].
Patients on Oral Anticoagulants
Depending on age, one sixth to one third of all acute ischaemic stroke patients are in atrial fibrillation, and many are on long-term oral anticoagulants when they arrive at the hospital, which creates problems for clinicians considering thrombolytic or endovascular therapy.[16, 17] Rapid reversal of Vitamin-K based anticoagulation to achieve an INR of <1.7 to permit iv thrombolysis is difficult [16]. The situation for patients treated with the novel direct oral anticoagulants (DOACs) is changing rapidly with the introduction into clinical practice of agents that can rapidly reverse the direct thrombin inhibitor dabigatran (idarucizumab). A small case series suggests that reversal of dabigatran prior to iv thrombolysis is safe [18], and Diener and others have proposed a management algorithm to handle such cases. [17] The agent that reversed factor X (adexanet) will be available in the near future.
Dose of Alteplase
Is a lower dose of iv alteplase preferable? The ENCHANTED study compared standard dose (0.9 mg/kg) with lower dose (0.6 mg/kg) alteplase [19]. Major symptomatic intracerebral haemorrhage occurred in 1.0% of the participants in the low-dose group and in 2.1% of the participants in the standard-dose group (P = 0.01). However, in terms of the effect on the proportion dead or disabled at 90 days, the lower dose did not meet the criteria for noninferiority. [19] The lower dose is widely used in Asia, and as a result of the trial, many clinicians will continue to use the lower dose because of fears of haemorrhage, despite the potential loss of efficacy. By contrast, in the West, clinicians may well tend to continue with the guideline approved standard dose, unless there is a particular concern about bleeding risk. [20]
Planning Service Delivery
There has been much debate about how best to organise stroke services to deliver reperfusion therapy to ensure the largest number of patients benefit. Most strokes occur in low and middle income countries, where delivery of basic acute stroke care is challenging [21] and beyond the scope of this article. As a result, the use of iv thrombolysis varies enormously around the world. In a systematic review of worldwide use of thrombolysis for stroke Berkowitz found that, of 214 countries and independent territories, 64 (30%) reported use of intravenous the average percentage treated tissue plasminogen activator for acute ischemic stroke; in the medical literature is 3% (1/36) of low-income, 19% (10/54) lower-middle-income, 33% (18/54) of upper-middle-income and 50% (35/70) of high-income-countries (test for trend, P < 0·001). [22] Within high-income countries like the USA, the proportion treated varies geographically [23], and treatment is not delivered to all that might benefit, though treatment rates are improving [24]. To deliver IVT/EVT equitably and affordably across a region or a country must be adapted to local resources will be a challenge, even for advanced economies, [23] and is beyond the scope of this article.
Conclusions
These new data confirm clearly that ‘time is brain’ and that the priority remains rapid recognition of stroke, transport to hospital with a fast-track stroke thrombolysis system of clinical and radiological assessment followed by prompt treatment with iv thrombolysis where appropriate or inclusion in a relevant trial designed to resolve one of the current uncertainties. These goals are best achieved within a well organised and dedicated stroke unit.
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Peter A. G. Sandercock received a donation of drug and placebo for a pilot study and a lecture fee paid to the department from Boehringer Ingelheim.
Stefano Ricci reports a grant from Boehringer Ingelheim.
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Sandercock, P.A.G., Ricci, S. Controversies in Thrombolysis. Curr Neurol Neurosci Rep 17, 60 (2017). https://doi.org/10.1007/s11910-017-0767-5
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DOI: https://doi.org/10.1007/s11910-017-0767-5