Correction
27 Oct 2017: Samarasekera N, Rodrigues MA, Toh PS, Al-Shahi Salman R (2017) Correction: Imaging features of intracerebral hemorrhage with cerebral amyloid angiopathy: Systematic review and meta-analysis. PLOS ONE 12(10): e0187386. https://doi.org/10.1371/journal.pone.0187386 View correction
Figures
Abstract
Background
We sought to summarize Computed Tomography (CT)/Magnetic Resonance Imaging (MRI) features of intracerebral hemorrhage (ICH) associated with cerebral amyloid angiopathy (CAA) in published observational radio-pathological studies.
Methods
In November 2016, two authors searched OVID Medline (1946-), Embase (1974-) and relevant bibliographies for studies of imaging features of lobar or cerebellar ICH with pathologically proven CAA (“CAA-associated ICH”). Two authors assessed studies’ diagnostic test accuracy methodology and independently extracted data.
Results
We identified 22 studies (21 cases series and one cross-sectional study with controls) of CT features in 297 adults, two cross-sectional studies of MRI features in 81 adults and one study which reported both CT and MRI features in 22 adults. Methods of CAA assessment varied, and rating of imaging features was not masked to pathology. The most frequently reported CT features of CAA-associated ICH in 21 case series were: subarachnoid extension (pooled proportion 82%, 95% CI 69–93%, I2 = 51%, 12 studies) and an irregular ICH border (64%, 95% CI 32–91%, I2 = 85%, five studies). CAA-associated ICH was more likely to be multiple on CT than non-CAA ICH in one cross-sectional study (CAA-associated ICH 7/41 vs. non-CAA ICH 0/42; χ2 = 7.8, p = 0.005). Superficial siderosis on MRI was present in 52% of CAA-associated ICH (95% CI 39–65%, I2 = 35%, 3 studies).
Citation: Samarasekera N, Rodrigues MA, Toh PS, Salman RA-S (2017) Imaging features of intracerebral hemorrhage with cerebral amyloid angiopathy: Systematic review and meta-analysis. PLoS ONE 12(7): e0180923. https://doi.org/10.1371/journal.pone.0180923
Editor: Jinglu Ai, University of Toronto, CANADA
Received: May 16, 2017; Accepted: June 23, 2017; Published: July 10, 2017
Copyright: © 2017 Samarasekera et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the paper and its Supporting Information files.
Funding: This work was supported by a Wellcome Trust Clinical Fellowship (Grant number 203699/Z/16/Z, https://wellcome.ac.uk/) to MAR.
Competing interests: The authors have declared that no competing interests exist.
Introduction
About 85% of ‘primary’ intracerebral haemorrhages (ICHs) have no specific underlying cause and are attributed to cerebral small vessel diseases, mostly arteriolosclerosis or cerebral amyloid angiopathy (CAA).[1,2] Arteriolosclerosis may underlie ICH in any location, whereas CAA only affects cortical and leptomeningeal vessels and is therefore associated with lobar and cerebellar ICH.[3] Accurate diagnosis of lobar or cerebellar ICH accompanied by pathologically-proven CAA (“CAA-associated ICH”) is important given its higher risk of recurrent ICH, anticoagulant-associated ICH and post-stroke dementia compared with arteriolosclerosis-associated ICH.[2,4]
Whilst definitive diagnosis of CAA requires histopathology, tissue samples from living patients are rarely available. In contrast, brain imaging is commonly performed in ICH, and may help differentiate these underlying pathologies. The magnetic resonance imaging (MRI)-based modified Boston criteria attribute lobar or cerebellar ICH to ‘probable CAA’ without pathological confirmation if there is either at least one other lobar or cerebellar ICH on brain imaging, or if at least one lobar cerebral or cerebellar microbleed or cortical superficial siderosis is present on gradient-echo brain MRI sequences.[5,6] The criteria have excellent sensitivity (95%, 95% CI 83–99%) and good specificity (81%, 95% CI 62–93%) in a hospital-based cohort with ICH,[5] but have not been externally validated. Positron emission tomography (PET) can directly detect amyloid ante-mortem. Whilst it shows good sensitivity (92%, 95% CI 72–99%) for presumed CAA-associated lobar ICH, its specificity is limited (65%, 95% CI 50–78%), reflecting the high frequency of parenchymal amyloid plaques among the healthy elderly.[7] Another drawback of MRI- and PET-based diagnostic criteria for CAA-associated ICH is the limited access to advanced imaging; these techniques may not be suitable in the acute setting, nor available, particularly in middle and low-income countries, where 75% of deaths from haemorrhagic stroke now occur.[8] In contrast, computed tomography (CT) is widely available, has few contraindications and is frequently used as the first test to investigate stroke. Therefore determining whether any CT features of ICH and the rest of the brain discriminate between CAA-associated ICH and other ICH is important.
The primary objective of this study was to systematically review and meta-analyse published diagnostic test accuracy studies or other observational radio-pathological studies describing features of CAA-associated lobar or cerebellar ICH.
Materials and methods
Search strategy and selection criteria
In November 2016 two authors (NS and PST) searched Ovid Medline (1946-) and Embase (1974-) using comprehensive electronic search strategies (S1 Appendix). One author (PST) also searched the bibliographies of relevant publications and Google scholar for other papers citing each included paper. We also searched our personal files. We did not publish a review protocol. We performed the study according to the PRISMA statement (S1 Checklist).[9]
Eligibility criteria
Published studies were eligible for inclusion if they described imaging features of lobar or cerebellar ICH associated with CAA, proven pathologically by brain biopsy, haematoma evacuation or post-mortem (primary outcome), regardless of sample size, language of publication, and study design.
Data collection
Two authors (NS and PST) screened all titles and abstracts for eligibility, removed duplicates and read the full text of articles that were potentially eligible for inclusion. Eligible studies were read in full by two authors (NS and PST) who extracted data independently on: study design, methods of assessment and grading of CAA, participant characteristics and imaging features of ICH. We resolved disagreements by discussion. If pertinent study attributes or data were unavailable or unclear in an eligible publication, we sought clarification from the authors by email.
Methodological assessment
Two authors (NS and PST) assessed each study using three items from the Joanna Briggs Critical Appraisal checklist for descriptive studies and case seriess1 (sample selection, definition of inclusion criteria, and identification of confounding factors [in particular patient age and dementia]) in addition to assessing whether rating of imaging features was blinded to pathological findings and vice versa. For cross-sectional studies, we applied the QUADAS-2 tool which judges the quality of diagnostic test accuracy studies based upon patient selection, the index test, reference standard and participant flow through the study.s2
Statistical analysis
If we identified multiple publications relating to the same cohort, we included only the largest study. For each case-series study, we determined the numbers of participants with lobar or cerebellar ICH accompanied by pathologically-proven CAA anywhere in the brain (“CAA-associated ICH”) and the frequency of the reported imaging characteristics of these participants’ brains. NS used the Stata command ‘metaprop’ to assess the prevalence of each imaging characteristic in CAA-associated ICH as a pooled proportion in a random-effects model with computation of confidence intervals using the ‘score’ method (Stata version 11.1, StataCorp LP, College Station, USA). NS assessed inconsistency using the I2 statistic. We sought to stratify our analyses by pre-ICH history of hypertension (present or not), first-ever vs. recurrent ICH and supratentorial lobar versus cerebellar ICH. We also assessed the frequency of reported combinations of imaging characteristics of CAA-associated ICH.
Results
Our search strategies identified 1,715 articles of which 22 (one cross-sectional study with controls [10] and 21 case series without controls [11–31]) described CT features of CAA-associated lobar or cerebellar ICH in 297 adults, two studies described MRI features [5,32] in 81 adults and one cross-sectional study [33] described both CT and MRI features in 22 adults (Fig 1). There were no PET studies. We excluded one hospital-based cross-sectional studys3 which did not report ICH location per participant and whose applicability to this review raised concern because of the age (mean 58 years; standard deviation 11) and haematoma locations (185/421 [44%] in the basal ganglia) of those with CAA-associated ICH.
Methodological quality of included studies
All 21 case series were hospital-based, using either consecutive cases in three (14%) studies [13,18,20] or selected hospital cases in the remainder, with a median sample size of 14 (IQR 7–37) (Table 1). Nine (43%) stated inclusion criteria.[11,13–15,17–21] Studies were retrospective bar one that selected consecutive patients from a prospectively recruited cohort.[13]
Of the two retrospective hospital-based cross-sectional studies using CT,[10,33] one included 41 cases [10] and the other 22 cases.[33] Both had a high risk of bias owing to inclusion of selected cases, potential misclassification since not all participants received the same reference standard and an unknown time interval between the index test (brain imaging) and the reference standard (histopathological diagnosis). The two cross-sectional studies assessing solely MRI were both retrospective hospital-based studies.[5,32] Again there was risk of bias due to potential misclassification since not all participants received the same reference standard.
Nine (36%) studies [15,17,19,21,24,25,27,30,31] distinguished first-ever from recurrent ICH. A pre-ICH history of hypertension or dementia were described in 19 (76%) [12,14–19,21–29,31–33] and 14 (56%) studies [11,12,14,15,17,19,22,25,27–31] respectively. Only four (16%) studies stated the interval between symptom onset and the diagnostic scan [20,22,23,31] and six (24%) studies stated the interval between the diagnostic scan and post-mortem or biopsy.[19–21,24,29,32] The number of raters of radiological features was mentioned in only four (16%) studies,[5,10,13,33] three of which used at least two raters per case.[5,10,13] Disagreements were resolved by consensus in two of these,[5,13] whilst the other study did not specify this.[10]
Pathological assessment.
The extent of brain sampling for CAA varied considerably between the studies (Table 2). All studies bar two (which did not state how the authors ascertained CAA [5,19]) used Congo Red staining, nine of which also used immunohistochemistry for all [15,17,22] or some cases.[11,13,21,24,32,33] Two studies described the severity of CAA rather than its presence or absence.[12,26] None of the studies stated whether CAA was rated blind to imaging findings or whether more than one rater rated CAA.
CT features of CAA-associated ICH
Characteristics of included participants in CT studies.
The majority of ICHs in the 319 participants were supratentorial lobar (n = 313). Three had a cerebellar ICH, one ICH was supratentorial lobar and cerebellum and two participants had a cerebellar ICH (but we could not determine whether it had occurred in isolation).
Frequency of CT features of CAA-associated ICH.
The most frequently reported imaging features of CAA-associated ICH in case series without controls were: multiple simultaneous ICHs (19 studies), intraventricular extension of ICH (15 studies), subarachnoid extension (14 studies) and an irregular ICH border (6 studies) (Table 3). The pooled proportion of participants with subarachnoid extension was 82% (95% CI 69–93%, I2 = 51%, 12 studies), irregular ICH border 64% (95% CI 32–91%, I2 = 85%, 5 studies), intraventricular hemorrhage 47% (95% CI 29%-65%, I2 = 76%, 14 studies) and multiple ICHs 37% (95% CI 18–58%, I2 = 75%, 14 studies), (Fig 2 and Table 3).
ES = effect size with 95% confidence intervals, n = number of participants with feature, N = number of participants with CAA-associated ICH.
17 studies described the locations of 346 ICHs in 262 patients.[10–12,14,15,17,18,20,22–27,29–31] The most frequent ICH locations were the frontal (83 [24%]) and parietal (83 [24%]) lobes. 72 (21%) ICHs were occipital, 58 (17%) were located in the temporal lobes and 7 (2%) were cerebellar. The remaining 43 ICHs involved multiple supratentorial lobes, with the parieto-occipital (15 [4%]) and fronto-parietal (14 [4%]) regions being the most frequently involved.
In one cross-sectional study,[10] CAA-associated ICHs were more likely to be multiple (CAA-associated ICH 7/41 vs. non-CAA ICH 0/42; χ2 = 7.8, p = 0.005) and have subarachnoid haemorrhage (CAA-associated ICH 26/41 vs. non-CAA ICH 11/42; p<0.05) compared to non-CAA ICHs. CAA-associated ICHs were also more likely be lobulated in comparison to non-CAA ICH (CAA-associated ICH 17/41 vs. non-CAA ICH 5/42; χ2 = 9.3, p = 0.002) but the proportion of ICHs with an irregular border did not differ between groups (CAA-associated ICH 15/41 vs. non-CAA ICH 22/42; χ2 = 2.1, p>0.05). However, the study did not explicitly define the terms ‘lobulated’ or ‘irregular border’. There was no difference in intraventricular haemorrhage between groups (CAA-associated ICH 10/41 vs. non-CAA ICH 11/42; p>0.05). In another cross-sectional study [33] there was no difference in either intraventricular hemorrhage (CAA-associated ICH 14/22 vs. non-CAA ICH 4/9; p = 0.279) or focal subarachnoid hemorrhage (CAA-associated ICH 11/22 vs. non-CAA ICH 2/9; p = 0.154) between groups.
CT features of CAA-associated ICH did not differ in first-ever vs recurrent ICH (S1 Fig) or those with a history of pre-stroke hypertension vs. those without (S2 Fig). We were unable to compare imaging features in lobar vs. cerebellar ICH given the paucity of infratentorial ICHs (n = 6). In 11 studies [12,18–22,25,27–29,31] of 75 ICHs reporting imaging features for each case of CAA-associated ICH, the three most frequently paired features were: intraventricular and subarachnoid extension (n = 21 [28%]), an irregular ICH border with subarachnoid extension (n = 14 [19%]) and a blood or fluid level within the haematoma with subarachnoid extension (n = 12 [16%]).
MRI features of CAA-associated ICH
Characteristics of included studies and participants.
We identified three retrospective, hospital-based cross-sectional studies, one of CAA-associated ICH which fulfilled the Boston criteria for CAA (we assumed CAA-associated ICH was either lobar or cerebellar [n = 27] vs. non-CAA ICH [n = 22]),[5] one of CAA-associated lobar ICH (n = 54) vs CAA without ICH (n = 51) [32] and a cross sectional study which used MRI on a subset of 17 adults with cortico-subcortical (i.e. lobar) ICH which fulfilled the Boston criteria for CAA vs. non-CAA ICH (n = 7).[33]
Frequency of MRI features of CAA-associated ICH.
The pooled proportion of focal or disseminated superficial siderosis in CAA-associated ICH was 52% (95% CI 39–65%, I2 = 35%, 3 studies; S3 Fig). The imaging features of ICH reported in one study were lobar brain microbleeds (n = 36 [67%]), severe centrum semi-ovale enlarged perivascular spaces (n = 29 [55%]), severe white matter hyperintensities (n = 13 [24%]) and severe basal ganglia enlarged perivascular spaces (n = 11 [21%]).[32] We excluded one study from this analysis which used CT to report white matter hyperintensities and did not report the frequency of lobar brain microbleeds.[33]
None of the studies assessing MRI features of CAA-associated ICH described ICH locations.
Sensitivity and specificity of the Boston criteria for detection of CAA-associated ICH.
From one study (n = 31) the sensitivity of the Boston criteria was 32% (95% CI 16–53%) and the specificity was 78% (95% CI 45–94%), however 7/31 participants did not have MRI.[33]
Discussion
In this systematic review and meta-analysis of 25 radio-pathological studies of 400 adults with CAA-associated lobar or cerebellar ICH, the most common CT imaging features in CAA-associated ICH were extension of the ICH into the subarachnoid space and an irregular ICH border. We found no difference in these CT imaging features of CAA-associated ICH in people with vs. without a pre-stroke history of hypertension and people with first-ever vs. recurrent lobar ICH. Superficial siderosis on MRI was visible in more than half of those with CAA-associated ICH.
This review benefited from comprehensive search strategies to ascertain relevant studies and thorough critical appraisal of all identified studies by two independent authors. However, study quality was limited, since most studies were hospital-based case series, which did not report the interval between symptom onset and the diagnostic scan (which may affect the imaging appearances of an ICH), had no blinding of assessors and lacked definitions of imaging variables or CAA-associated ICH.
We demonstrated that subarachnoid extension was a frequent finding in CAA-associated ICH, which may be in keeping with CAA preferentially affecting leptomeningeal and cortical vessels which could rupture into the subarachnoid space.[34] However, this may also be due to the selection bias of pathological studies, since subarachnoid extension is associated with larger ICH volumes,[35] or simply anatomy rather than underlying pathology since subarachnoid extension is more frequent in lobar ICH compared to non-lobar ICH.[1]
CAA-associated ICHs frequently had an irregular border. Whilst the pathophysiology of this finding is not fully understood, it may reflect deficiencies in endothelial and subendothelial functioning in CAA-affected vessels and/or impaired vasoconstriction, resulting in detrimental effects on haemostasis.[10,36,37] Alternatively, selection bias in radio-pathological studies may account for this finding since an irregular ICH border is associated with death.[38]
Although we found no difference in imaging characteristics between people with first-ever and recurrent ICH, the sample size was small. Multiple ICH was more frequent in CAA-associated ICH in one cross-sectional study, and both multiple and recurrent ICH may be in keeping with a biological gradient for CAA that is yet to be established.[3] Similarly we could not detect a difference between people with pre-ICH hypertension and those without, although this may be due to selection bias, variable definitions of hypertension, inclusion of people with both first-ever and recurrent ICH, or small sample sizes.
Nearly half of people with CAA-associated ICH in MRI studies did not have superficial siderosis or severe centrum semiovale enlarged perivascular spaces and nearly one third did not have lobar microbleeds, underlining the need for further studies to determine which MRI features–alone or in combination–are most sensitive for CAA-associated ICH. The modified Boston criteria had limited sensitivity with reasonable specificity in a small hospital-based cohort of adults with ICH, although not all participants underwent MRI.[33] Nonetheless, this highlights the requirement for external validation of these criteria to better define their diagnostic accuracy.
Differentiating CAA- and non-CAA-associated ICH is important because of potential differences in management and prognosis.[2,4] The optimal approach would use an imaging modality that is available worldwide, given that the greatest global burden of ICH is now in middle and low income countries.[8] CT, in contrast to MRI and PET, is widely available, has few contraindications and is frequently used in the acute setting for ICH. CT-based criteria for CAA-associated lobar ICH may therefore be more widely applicable and practical than those requiring advanced imaging such as MRI or PET. Our systematic review showed that no such criteria exist.
Future work should focus on performing well-designed studies to produce accurate diagnostic criteria for CAA-associated ICH with low risk of bias. The ideal study design would be a diagnostic test accuracy study of an unselected, population-based cohort, with a systematic examination of a pathological reference standard, examining the diagnostic utility of relevant imaging features, such as subarachnoid and intraventricular extension, irregular ICH border and multiple simultaneous acute ICHs identified in this review. The imaging features should clearly and reliably defined, particularly those that are subjective, such as ‘irregular’ or ‘lobulated’ ICH.[39,40] Given the variable assessment of CAA, its patchy distribution with vulnerability to sampling variation[41] and co-existence with other small vessel diseases,[42] a standard definition of ‘CAA-associated ICH’ is also essential. Pathological and imaging assessment should be blinded, and assessment by multiple raters is required to determine inter-observer variability.
In conclusion, this systematic review of radio-pathological studies showed that subarachnoid extension and an irregular border are the most common imaging features of CAA-associated lobar and cerebellar ICH. However, the diagnostic value of these and other imaging features needs to be assessed in rigorous diagnostic test accuracy studies. CT-based diagnostic criteria for CAA-associated ICH would be the most widely applicable, particularly for frail patients who cannot tolerate MRI and PET, and in low-middle income countries where advanced imaging is not available and the greatest global burden of ICH lies now and in the future.[8]
Supporting information
S1 Appendix. OVID Medline and Embase search strategies and supporting material references.
https://doi.org/10.1371/journal.pone.0180923.s001
(DOCX)
S1 Fig. Meta-analysis of the relative risk of imaging features in first-ever vs. recurrent CAA-associated ICH.
n = number of participants with feature, N = denominator, RR = relative risk, (95% CI) = 95% confidence intervals.
https://doi.org/10.1371/journal.pone.0180923.s003
(TIF)
S2 Fig. Meta-analysis of the relative risk of imaging features in people with CAA-associated ICH and a history of hypertension vs. people without a history of hypertension.
n = number of participants with feature, N = denominator, RR = relative risk, (95% CI) = 95% confidence intervals.
https://doi.org/10.1371/journal.pone.0180923.s004
(TIF)
S3 Fig. Superficial siderosis in CAA-associated ICH—Pooled proportion meta-analysis.
ES = effect size, n = number of participants with superficial siderosis, N = total number with CAA-associated ICH, (95% CI) = 95% confidence intervals.
https://doi.org/10.1371/journal.pone.0180923.s005
(TIF)
References
- 1. Samarasekera N, Fonville AF, Lerpiniere C, Farrall A, Wardlaw JM, White PM, Smith C, Al-Shahi Salman R (2015) The influence of intracerebral haemorrhage location on incidence, characteristics and outcome: a population-based study. Stroke 46: 361–368. pmid:25586833
- 2. Charidimou A, Gang Q, Werring DJ (2012) Sporadic cerebral amyloid angiopathy revisited: recent insights into pathophysiology and clinical spectrum. Journal of Neurology, Neurosurgery & Psychiatry 83: 124–137.
- 3. Samarasekera N, Smith C, Al-Shahi Salman R (2012) The association between cerebral amyloid angiopathy and intracerebral haemorrhage: systematic review and meta-analysis. Journal of Neurology, Neurosurgery & Psychiatry 83: 275–281.
- 4. Haley KE, Greenberg SM FAU, Gurol ME (2013) Cerebral microbleeds and macrobleeds: should they influence our recommendations for antithrombotic therapies? Curr Cardiol Rep 15: 425. pmid:24122195
- 5. Linn J, Halpin A, Demaerel P, Ruhland J, Giese AD, Dichgans M, van Buchem MA, Bruckmann H, Greenberg SM (2010) Prevalence of superficial siderosis in patients with cerebral amyloid angiopathy. Neurology 74: 1346–1350. pmid:20421578
- 6. Knudsen KA, Rosand J, Karluk D, Greenberg SM (2001) Clinical diagnosis of cerebral amyloid angiopathy: validation of the Boston criteria. Neurology 56: 537–539. pmid:11222803
- 7. Farid K, Charidimou A, Baron JC (2017) Amyloid positron emission tomography in sporadic cerebral amyloid angiopathy: A systematic critical update. NeuroImage: Clinical 15: 247–263.
- 8. Feigin VL, Krishnamurthi RV, Parmar P, Norrving B, Mensah GA, Bennett DA, Barker-Collo S, Moran AE, Sacco RL, Truelsen T, Davis S, Pandian JD, Naghavi M, Forouzanfar MH, Nguyen G, Johnson CO, Vos T, Meretoja A, Murray CJ, Roth GA (2015) Update on the Global Burden of Ischemic and Hemorrhagic Stroke in 1990–2013: The GBD 2013 Study. Neuroepidemiology 45: 161–176. pmid:26505981
- 9.
Moher D, Liberati AF, Tetzlaff JF, Altman DG (Preferred reporting items for systematic reviews and meta-analyses: the PRISMA statement.
- 10. Lang EW, Ren YZ, Preul C, Hugo HH, Hempelmann RG, Buhl R, Barth H, Klinge H, Mehdorn HM (2001) Stroke pattern interpretation: the variability of hypertensive versus amyloid angiopathy hemorrhage. Cerebrovascular Diseases 12: 121–130. pmid:11490106
- 11. Hirohata M, Yoshita M, Ishida C, Ikeda SI, Tamaoka A, Kuzuhara S, Shoji M, Ando Y, Tokuda T, Yamada M (2010) Clinical features of non-hypertensive lobar intracerebral hemorrhage related to cerebral amyloid angiopathy. Eur J Neurol 17: 823–829. pmid:20158508
- 12. Panicker JN, Nagaraja D, Chickabasaviah YT (2010) Cerebral amyloid angiopathy: A clinicopathological study of three cases. Ann Indian Acad Neurol 13: 216–220. pmid:21085537
- 13. Patel P, FitzMaurice E, Nandigam RNK, Auluck P, Viswanathan A, Goldstein JN, Rosand J, Greenberg SM, Smith EE (2009) Association of Subdural Hematoma With Increased Mortality in Lobar Intracerebral Hemorrhage. Archives of Neurology 66: 79–84. pmid:19139303
- 14. Chen CS, Lo YK, Yan SH, Lin YT, Lai PH, Lo YS (2004) Lobar cerebral hemorrhage from amyloid angiopathy: clinical, neuroimaging, pathologic and outcome correlations. Acta Neurol Taiwan 13: 14–19. pmid:15315296
- 15. Oide T, Takahashi H, Yutani C, Ishihara T, Ikeda S (2003) Relationship between lobar intracerebral hemorrhage and leukoencephalopathy associated with cerebral amyloid angiopathy: clinicopathological study of 64 Japanese patients. Amyloid 10: 136–143. pmid:14640026
- 16. Wang X, Sun B, Rao M (2000) The observation on the causes, pathogenic mechanisms and clinical characteristics for acute multifocal cerebral hemorrhage. Chinese Journal of Neurology 33: 83–85.
- 17. Izumihara A, Ishihara T, Iwamoto N, Yamashita K, Ito H (1999) Postoperative outcome of 37 patients with lobar intracerebral hemorrhage related to cerebral amyloid angiopathy. Stroke 30: 29–33. pmid:9880384
- 18. Hagen T (1999) [Intracerebral hemorrhage in the context of amyloid angiopathy]. Radiologe 39: 847–854. pmid:10550383
- 19. Millar JH, Wardlaw JM, Lammie GA (1999) Intracerebral haemorrhage and cerebral amyloid angiopathy: CT features with pathological correlation. Clinical Radiology 54: 422–429. pmid:10437691
- 20. Minakawa T, Takeuchi S, Sasaki O, Koizumi T, Honad Y, Fujii Y, Ozawa T, Ogawa H, Koike T, Tanaka R (1995) Surgical experience with massive lobar haemorrhage caused by cerebral amyloid angiopathy. Acta Neurochir (Wien) 132: 48–52.
- 21. Wakai S, Kumakura N, Nagai M (1992) Lobar intracerebral hemorrhage. A clinical, radiographic, and pathological study of 29 consecutive operated cases with negative angiography. J Neurosurg 76: 231–238. pmid:1730952
- 22. Yong WH, Robert ME, Secor DL, Kleikamp TJ, Vinters HV (1992) Cerebral hemorrhage with biopsy-proved amyloid angiopathy. Arch Neurol 49: 51–58. pmid:1728264
- 23. Xu HQ (1990) [Intracerebral hemorrhage related with cerebral amyloid angiopathy]. Zhonghua Shen Jing Jing Shen Ke Za Zhi 23: 345–7, 384. pmid:2098245
- 24. Andoh Y, Wakai S, Nagai M, Honma K, Fujihara S (1989) [Lobar intracerebral hemorrhage secondary to cerebral amyloid angiopathy: a clinicopathologic study of three operated cases]. No To Shinkei 41: 1217–1223. pmid:2697377
- 25. Sobel DF, Baker E, Anderson B, Kretzschmar H (1985) Cerebral amyloid angiopathy associated with massive intracerebral hemorrhage. Neuroradiology 27: 318–321. pmid:4047387
- 26. Cosgrove GR, Leblanc R, Meagher-Villemure K, Ethier R (1985) Cerebral amyloid angiopathy. Neurology 35: 625–631. pmid:3990962
- 27. Brown RT, Coates RK, Gilbert JJ (1985) Radiographic-pathologic correlation in cerebral amyloid angiopathy. A review of 12 patients. J Can Assoc Radiol 36: 308–311. pmid:4086501
- 28. Gray F, Dubas F, Roullet E, Escourolle R (1985) Leukoencephalopathy in diffuse hemorrhagic cerebral amyloid angiopathy. Ann Neurol 18: 54–59. pmid:4037751
- 29. Kalyan-Raman UP, Kalyan-Raman K (1984) Cerebral amyloid angiopathy causing intracranial hemorrhage. Ann Neurol 16: 321–329. pmid:6385824
- 30. Patel DV, Hier DB, Thomas CM, Hemmati M (1984) Intracerebral hemorrhage secondary to cerebral amyloid angiopathy. Radiology 151: 397–400. pmid:6709910
- 31. Wagle WA, Smith TW, Weiner M (1984) Intracerebral hemorrhage caused by cerebral amyloid angiopathy: radiographic-pathologic correlation. AJNR Am J Neuroradiol 5: 171–176. pmid:6422718
- 32. Charidimou A, Martinez-Ramirez S, Shoamanesh A, Oliveira-Filho J, Frosch M, Vashkevich A, Ayres A, Rosand J, Gurol ME, Greenberg SM, Viswanathan A (2015) Cerebral amyloid angiopathy with and without hemorrhage: evidence for different disease phenotypes. Neurology 84: 1206–1212. pmid:25716356
- 33. Doden T, Sato H, Sasahara E, Murata T, Yako T, Kitazawa K, Higuchi K, Kobayashi S, Hashimoto T (2016) Clinico-Radiological Characteristics and Pathological Diagnosis of Cerebral Amyloid Angiopathy-Related Intracerebral Hemorrhage. Journal of Stroke and Cerebrovascular Diseases 25: 1736–1745. pmid:27151414
- 34. Thal DR, Ghebremedhin E, Orantes M, Wiestler OD (2003) Vascular pathology in Alzheimer disease: correlation of cerebral amyloid angiopathy and arteriosclerosis/lipohyalinosis with cognitive decline. J Neuropathol Exp Neurol 62: 1287–1301. pmid:14692704
- 35. Chen G, Arima H, Wu G, Heeley E, Delcourt C, Zhang P, Rabinstein AA, Robinson T, Stapf C, Huang Y, Song L, Yang J, Wang X, Li Q, Chen X, Chalmers J, Anderson C (2013) Subarachnoid Extension of Intracerebral Hemorrhage and 90-Day Outcomes in INTERACT2. Stroke 45: 258–260. pmid:24149007
- 36. Ramsay DA, Penswick JL FAU, Robertson DM (1990) Fatal streptokinase-induced intracerebral haemorrhage in cerebral amyloid angiopathy. The Canadian Journal of Neurological Sciences 17: 336–341. pmid:2207893
- 37. Thomas T, Thomas GF, McLendon CF, Sutton TF, Mullan M (1996) beta-Amyloid-mediated vasoactivity and vascular endothelial damage. Nature 380: 168–171. pmid:8600393
- 38. Delcourt C, Zhang S, Arima H, Sato S, Salman RA, Wang X, Davies L, Stapf C, Robinson T, Lavados PM, Chalmers J, Heeley E, Liu M, Lindley RI, Anderson CS (2016) Significance of Hematoma Shape and Density in Intracerebral Hemorrhage: The Intensive Blood Pressure Reduction in Acute Intracerebral Hemorrhage Trial Study. Stroke 47: 1227–1232. pmid:27073236
- 39. Bossuyt PM, Reitsma JB, Bruns DE, Gatsonis CA, Glasziou PP, Irwig L, Lijmer JG, Moher D, Rennie D, de Vet HC, Kressel HY, Rifai N, Golub RM, Altman DG, Hooft L, Korevaar DA, Cohen JF (2015) STARD 2015: an updated list of essential items for reporting diagnostic accuracy studies. British Medical Journal 351: h5527. pmid:26511519
- 40. Collins GS, Reitsma JB, Altman DG, Moons KG (2015) Transparent reporting of a multivariable prediction model for individual prognosis or diagnosis (TRIPOD): the TRIPOD statement. British Medical Journal 350: g7594. pmid:25569120
- 41. Greenberg SM, Vonsattel JP (1997) Diagnosis of cerebral amyloid angiopathy. Sensitivity and specificity of cortical biopsy. Stroke 28: 1418–1422. pmid:9227694
- 42. Matthews FE, Brayne C, Lowe J, McKeith I, Wharton SB, Ince P (2009) Epidemiological pathology of dementia: attributable-risks at death in the Medical Research Council Cognitive Function and Ageing Study. PLoS Medicine / Public Library of Science 6: e1000180.