DWI in transient global amnesia and TIA: proposal
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神经科学杂志 2005年第3期
1 Department of Neurology, Technical University of Munich, Germany
2 Department of Neuroradiology, Technical University of Munich, Germany
ABSTRACT
There are conflicting reports concerning signal intensity changes in transient global amnesia (TGA) using diffusion weighted imaging (DWI). We prospectively analysed DWI signal intensity changes in TIA and TGA patients, and compared the clinical characteristics and risk factors of both groups. Using DWI and conventional T1 and T2 weighted turbo spin echo sequences, 28 patients with acute TGA (13 men, mean age 61.5 years) and 74 TIA patients (47 men, mean age 62.4 years) were studied within 48 hours after symptom onset. Every patient underwent an intensive diagnostic investigation. In 10/28 (36%) of the TGA patients and 21/74 (28%) of the TIA patients, DWI signal intensity changes occurred. The time to DWI and the duration of symptoms were comparable in TIA and TGA patients. Overall, TIA patients showed an increased prevalence of vascular risk factors compared with TGA patients. In the TGA group, patients with abnormal DWI showed carotid atherosclerosis significantly more frequently. Based on our data, we suggest that the aetiology of TGA could be explained by an ischaemic event; due to arterial thrombembolic ischaemia in one subgroup, particularly in those patients with increased vascular risk factors, and due to venous ischaemia in another subgroup with valsalva-like activities before symptom onset.
Abbreviations: ADC, apparent diffusion coefficient; DWI, diffusion weighted imaging; IMT, intima–media thickness; PS, plaque score; TGA, transient global amnesia; TIA, transient ischaemic attack
The aetiology and pathogenesis of transient global amnesia (TGA) is still unclear. Several different causes such as transient ischaemic attack (TIA), seizure, migraine, and venous congestion with consecutive ischaemia of memory relevant structures have been discussed previously.1 Several investigators have used diffusion weighted imaging (DWI) to further examine the aetiology of TGA and reported controversial results.2–4 Delayed DWI abnormalities were reported in 100% of a TGA population.5 Interestingly, DWI abnormalities were also reported in 21–67% of TIA.6–8 As none of the recent studies evaluated patients with acute TIA and TGA using early DWI, we prospectively investigated the prevalence of DWI signal intensities and vascular risk factors in patients with acute TGA compared with those with TIA.
METHODS
Between June 2000 and June 2003, 256 TIA patients were treated at the stroke unit of the Department of Neurology. In 74 patients, a DWI was performed within 48 hours after symptom onset. All of these patients have been included (mean age 62.4 years; 95% confidence interval (CI) 58.5 to 66.3). We also treated 35 patients with proven pure TGA between January 2000 and September 2003. In 28 of these patients (13 men, mean age 61.5 years; 95% CI 57.5 to 65.5), a DWI was performed within 48 hours of symptom onset. TGA was diagnosed strictly according to well established criteria.9,10 TIA was defined as an acute transient focal neurological deficit caused by vascular disease that reversed totally within 24 hours.11 All TIA and TGA patients underwent an intensive diagnostic investigation including physical and neurological examination, duplex sonography of the carotid arteries, transcranial dopplersonography, 12 lead ECG, transthoracic echocardiography, and analysis of cardio-vascular risk factors such as body mass index, prevalence of smoking, hypercholesterolaemia, arterial hypertension, diabetes mellitus, ischaemic heart disease, and carotid atherosclerosis. We also determined the intima–media thickness (IMT) of the common carotid artery, as described previously.12 The plaque score (PS) was calculated by summing the maximum thickness (in mm) of each plaque located in bilateral carotid arteries as previously described by Nagai et al.13 In TGA patients, we performed an EEG to rule out an epileptic seizure.
MRI measurements
In TGA patients, transversal T1 and T2 sequences, and two DWI sequences (usually a transversal plane aligned to the course of the hippocampus and a coronal sequence angulated perpendicular to the hippocampus) were obtained with a 1.5 Telsa MRI (Magnetom Symphony; Siemens Medical Systems, Erlangen, Germany). The DWI imaging parameters have been described in detail previously.14 In TIA patients we performed conventional T1 and T2 weighted sequences, as well as at least one transversal DWI sequence using the same parameters, without angulation to the hippocampus. A DWI scan was considered positive if the hyperintensive region was confirmed in a second coronal or sagittal plane and if the scan revealed an area of hypointensity on the apparent diffusion coefficient (ADC) map.
The regions of hyperintensity on the b = 1000 image and hypodensity on the ADC images were analysed by manually outlining the regions of interest using an image analysing system (Sigma Scan Pro; SPSS, Chicago, IL, USA) as described previously.14 Additionally we analysed the ratio between the lesion and corresponding normal contralateral tissue average signal intensity (rAI) on b = 1000 (rAIb = 1000) and ADC images (rAI ADC). The images were additionally analysed by a blinded neuroradiologist (MR).
Statistical analysis
All values are given as mean (95% CI). Between group comparisons were performed with Fisher’s exact test and Student’s t test for normally distributed data. For non-normally distributed data, the Wilcoxon test was used. Values of p<0.05 were considered significant. For assessing the inter-rater agreement, we used kappa values.
RESULTS
On DWI, 21/74 TIA patients (28%) and 10/28 TGA patients (36%) showed signal intensity changes. The time to DWI was comparable in both groups. In TGA patients, all the lesions were located in memory relevant structures such as the hippocampus, the gyrus parahippocampalis, and the medial temporal lobe. Fig 1 gives an example of a typical DWI lesion in the TGA group. Of the TGA patients, 17/28 (54%) reported valsalva-like activities, and 10 (36%) described extraordinary emotional stress at the beginning of symptoms. TGA patients with hyperintensive DWI lesions (TGA+) showed an increased incidence of vascular risk factors such as hypertension, hypercholesterolaemia, and smoking, an increased IMT (1.03 mm v 0.76 mm; p = 0.002),) and a higher prevalence of carotid plaques (70% v 17%, p = 0.01) compared with those without lesions (TGA–). In addition, the duration of symptoms (4.3 h v 7.2 h) and the time to DWI (26.1 h v 19.7 h) did not differ significantly between the TGA subgroups.
As expected, the vascular risk profile was different in TIA and TGA patients (table 1). The rAI b = 1000 was comparable in TIA and TGA patients, whereas the rAI ADC was significantly higher in TGA than in TIA patients (0.91 v 0.85; p = 0.001; table 1). Analysing the subgroup of TIA and TGA patients with abnormal DWI (TIA+ and TGA+), we detected com-parable risk factors in both groups. TIA patients showed a significant increased PS (7.53 mm v 4.13 mm, p = 0.02). The time to DWI was significantly shorter in TIA+ patients compared with TGA+ patients (14.6 h (95% CI 8.0 to 21.1) v 26.1 h (16.6 to 35.6); p = 0.03). The kappa value for inter-rater agreement was 0.85 (0.64 to 1.05), indicating very good reliability.
DISCUSSION
One of the hypotheses for the aetiology of TGA is transient cerebral ischaemia. In contrast to the findings in TIA patients, the results of DWI studies in TGA patients are controversial. There are several case reports describing DWI signal intensity changes in TGA patients,15–17 whereas two larger studies found no DWI abnormalities in TGA patients.3,4 In contrast, Sedlaczek et al5 previously described small parenchymal hyperintensities on DWI on day 2 in 11/11 patients with clinically identified TGA in a serial DWI study. Hence, the investigators conclude that the aetiology of TGA is a primarily ischaemic event. In our study, we observed a similar prevalence of DWI lesions in TGA and TIA patients. The different prevalence of DWI lesions in our study compared with that of Sedlaczek et al5 might be explained by a later onset of DWI lesions in TGA patients. Interestingly, in the subgroup of TGA+ patients the time to DWI was 26 h compared with 19 h in the TGA– group, which may support this argument. As we did not perform a serial DWI study, we cannot rule out the possibility that additionally DWI lesions could have been detected in later images. Owing to the comparable incidence of DWI lesions in TGA and TIA patients, we further evaluated the vascular risk profile of TGA and TIA patients, particularly of the subgroup with and without pathological DWI, in more detail. As expected, we found a lower incidence of vascular risk factors in TGA patients compared with TIA patients. Interestingly, TGA+ patients showed a higher vascular risk profile, significantly more frequent carotid atherosclerosis, and an increased IMT than did TGA– patients. These findings may support, particularly in this subgroup of TGA patients, an arterial embolic event. Nevertheless, there are several points that question an arterial ischaemic aetiology in all TGA patients: the different cardiovascular risk profile, the better long term outcome, and the low recurrence rate.9,18,19
Lewis1 pointed out that TGA might be caused by venous congestion as a consequence of a retrograde transmission of high venous pressure after valsalva-like activities. This hypothesis was confirmed by the finding of a higher incidence of a retrograde flow pattern in the internal jugular vein in TGA.20–22 Others have proposed a specific anxious personality trait in TGA patients, which might induce vasoconstriction due to hyperventilation during an emotional arousal.23 Therefore, temporary hypoperfusion either due to venous congestion or vasoconstriction due to hyperventilation might cause TGA. The increased vulnerability of the hippocampus and the venous drainage might help to explain why memory structures are first involved.22 As DWI lesions in venous infarction are more heterogeneous,24 it is conceivable that DWI lesions are underestimated in patients with venous ischaemia. Interestingly, the ADC ratio was significantly higher in TGA patients than in TIA patients. Increased diffusion does not necessary mean ischaemia, and it occurs even in multiple sclerosis and seizure. However, ADC changes seen during post-ictal DWI are complex, including generalised ADC changes, cortical hyperdensities, no major changes, and even ADC increase.25 The lesions we found in our population were all quite similar and comparable with DWI changes in TIA patients. Additionally, if the DWI lesions in our study were due to epileptic changes, it might be postulated that at least in a few TGA patients, EEG changes should occur.
Based on our data it might be speculated that transient ischaemia, either embolic or due to venous congestion in memory relevant structures, cause TGA and that the transient abnormalities in brain function might be too small to be detected in every TGA patient using DWI. In both groups, emotional distress might act as a pathogenic cofactor.
REFERENCES
Lewis SL. Aetiology of transient global amnesia. Lancet 1998;352:397–9.
Strupp M, Bruning R, Wu RH, et al. Diffusion-weighted MRI in transient global amnesia: elevated signal intensity in the left mesial temporal lobe in 7 of 10 patients. Ann Neurol 1998;43:164–70.
Gass A, Gaa J, Hirsch J, et al. Lack of evidence of acute ischemic tissue change in transient global amnesia on single-shot echo-planar diffusion-weighted MRI. Stroke 1999;30:2070–2.
Huber R, Aschoff AJ, Ludolph AC, et al. Transient global amnesia. Evidence against vascular ischemic etiology from diffusion weighted imaging. J Neurol 2002;249:1520–4.
Sedlaczek O, Hirsch J, Grips E, et al. Delayed hippocampal DWI changes are associated with transient global amnesia. Cerebrovascular Dis 2002;13 (Suppl 3) :58.
Kidwell CS, Alger JR, Di Salle F, et al. Diffusion MRI in patients with transient ischemic attacks. Stroke 1999;30:1174–80.
Rovira A, Rovira-Gols A, Pedraza S, et al. Diffusion-weighted MR imaging in the acute phase of transient ischemic attacks. AJNR Am J Neuroradiol 2002;23:77–83.
Crisostomo RA, Garcia MM, Tong DC. Detection of diffusion-weighted MRI abnormalities in patients with transient ischemic attack: correlation with clinical characteristics. Stroke 2003;34:932–7.
Hodges JR, Warlow CP. The aetiology of transient global amnesia. A case-control study of 114 cases with prospective follow-up. Brain 1990;113:639–57.
Caplan LR. Transient global amnesia. Amsterdam: Elsevier Science Publishers, 1985.
Special report from the National Institute of Neurological Disorders and Stroke. Classification of cerebrovascular diseases III. Stroke 1990;21:637–76.
Sander D, Winbeck K, Klingelhofer J, et al. Enhanced progression of early carotid atherosclerosis is related to Chlamydia pneumoniae (Taiwan acute respiratory) seropositivity. Circulation 2001;103:1390–5.
Nagai Y, Kitagawa K, Yamagami H, et al. Carotid artery intima-media thickness and plaque score for the risk assessment of stroke subtypes. Ultrasound Med Biol 2002;28:1239–43.
Winbeck K, Bruckmaier K, Etgen T, et al. Transient ischemic attack and stroke can be differentiated by analyzing early diffusion-weighted imaging signal intensity changes. Stroke 2004;35:1095–9.
Inamura T, Nakazaki K, Yasuda O, et al. (A lesion diagnosed by MRI in a case of transient global amnesia). No To Shinkei 2002;54:419–22.
Matsui M, Imamura T, Sakamoto S, et al. Transient global amnesia: increased signal intensity in the right hippocampus on diffusion-weighted magnetic resonance imaging. Neuroradiology 2002;44:235–8.
Greer DM, Schaefer PW, Schwamm LH. Unilateral temporal lobe stroke causing ischemic transient global amnesia: role for diffusion-weighted imaging in the initial evaluation. J Neuroimaging 2001;11:317–19.
Gandolfo C, Caponnetto C, Conti M, et al. Prognosis of transient global amnesia: a long-term follow-up study. Eur Neurol 1992;32:52–7.
Zorzon M, Antonutti L, Mase G, et al. Transient global amnesia and transient ischemic attack. Natural history, vascular risk factors, and associated conditions. Stroke 1995;26:1536–42.
Sander D, Winbeck K, Etgen T, et al. Disturbance of venous flow patterns in patients with transient global amnesia. Lancet 2000;356:1982–4.
Akkawi NM, Agosti C, Rozzini L, et al. Transient global amnesia and disturbance of venous flow patterns. Lancet 2001;357:957.
Maalikjy Akkawi N, Agosti C, et al. Transient global amnesia: a clinical and sonographic study. Eur Neurol 2003;49:67–71.
Pantoni L, Lamassa M, Inzitari D. Transient global amnesia: a review emphasizing pathogenic aspects. Acta Neurol Scand 2000;102:275–83.
Ducreux D, Petit-Lacour MC, Benoudiba F, et al. Diffusion-weighted imaging in a case of Wernicke encephalopathy. J Neuroradiol 2002;29:39–42.
Hufnagel A, Weber J, Marks S, et al. Brain diffusion after single seizures. Epilepsia 2003;44:54–63.(K Winbeck, T Etgen, H G v)
2 Department of Neuroradiology, Technical University of Munich, Germany
ABSTRACT
There are conflicting reports concerning signal intensity changes in transient global amnesia (TGA) using diffusion weighted imaging (DWI). We prospectively analysed DWI signal intensity changes in TIA and TGA patients, and compared the clinical characteristics and risk factors of both groups. Using DWI and conventional T1 and T2 weighted turbo spin echo sequences, 28 patients with acute TGA (13 men, mean age 61.5 years) and 74 TIA patients (47 men, mean age 62.4 years) were studied within 48 hours after symptom onset. Every patient underwent an intensive diagnostic investigation. In 10/28 (36%) of the TGA patients and 21/74 (28%) of the TIA patients, DWI signal intensity changes occurred. The time to DWI and the duration of symptoms were comparable in TIA and TGA patients. Overall, TIA patients showed an increased prevalence of vascular risk factors compared with TGA patients. In the TGA group, patients with abnormal DWI showed carotid atherosclerosis significantly more frequently. Based on our data, we suggest that the aetiology of TGA could be explained by an ischaemic event; due to arterial thrombembolic ischaemia in one subgroup, particularly in those patients with increased vascular risk factors, and due to venous ischaemia in another subgroup with valsalva-like activities before symptom onset.
Abbreviations: ADC, apparent diffusion coefficient; DWI, diffusion weighted imaging; IMT, intima–media thickness; PS, plaque score; TGA, transient global amnesia; TIA, transient ischaemic attack
The aetiology and pathogenesis of transient global amnesia (TGA) is still unclear. Several different causes such as transient ischaemic attack (TIA), seizure, migraine, and venous congestion with consecutive ischaemia of memory relevant structures have been discussed previously.1 Several investigators have used diffusion weighted imaging (DWI) to further examine the aetiology of TGA and reported controversial results.2–4 Delayed DWI abnormalities were reported in 100% of a TGA population.5 Interestingly, DWI abnormalities were also reported in 21–67% of TIA.6–8 As none of the recent studies evaluated patients with acute TIA and TGA using early DWI, we prospectively investigated the prevalence of DWI signal intensities and vascular risk factors in patients with acute TGA compared with those with TIA.
METHODS
Between June 2000 and June 2003, 256 TIA patients were treated at the stroke unit of the Department of Neurology. In 74 patients, a DWI was performed within 48 hours after symptom onset. All of these patients have been included (mean age 62.4 years; 95% confidence interval (CI) 58.5 to 66.3). We also treated 35 patients with proven pure TGA between January 2000 and September 2003. In 28 of these patients (13 men, mean age 61.5 years; 95% CI 57.5 to 65.5), a DWI was performed within 48 hours of symptom onset. TGA was diagnosed strictly according to well established criteria.9,10 TIA was defined as an acute transient focal neurological deficit caused by vascular disease that reversed totally within 24 hours.11 All TIA and TGA patients underwent an intensive diagnostic investigation including physical and neurological examination, duplex sonography of the carotid arteries, transcranial dopplersonography, 12 lead ECG, transthoracic echocardiography, and analysis of cardio-vascular risk factors such as body mass index, prevalence of smoking, hypercholesterolaemia, arterial hypertension, diabetes mellitus, ischaemic heart disease, and carotid atherosclerosis. We also determined the intima–media thickness (IMT) of the common carotid artery, as described previously.12 The plaque score (PS) was calculated by summing the maximum thickness (in mm) of each plaque located in bilateral carotid arteries as previously described by Nagai et al.13 In TGA patients, we performed an EEG to rule out an epileptic seizure.
MRI measurements
In TGA patients, transversal T1 and T2 sequences, and two DWI sequences (usually a transversal plane aligned to the course of the hippocampus and a coronal sequence angulated perpendicular to the hippocampus) were obtained with a 1.5 Telsa MRI (Magnetom Symphony; Siemens Medical Systems, Erlangen, Germany). The DWI imaging parameters have been described in detail previously.14 In TIA patients we performed conventional T1 and T2 weighted sequences, as well as at least one transversal DWI sequence using the same parameters, without angulation to the hippocampus. A DWI scan was considered positive if the hyperintensive region was confirmed in a second coronal or sagittal plane and if the scan revealed an area of hypointensity on the apparent diffusion coefficient (ADC) map.
The regions of hyperintensity on the b = 1000 image and hypodensity on the ADC images were analysed by manually outlining the regions of interest using an image analysing system (Sigma Scan Pro; SPSS, Chicago, IL, USA) as described previously.14 Additionally we analysed the ratio between the lesion and corresponding normal contralateral tissue average signal intensity (rAI) on b = 1000 (rAIb = 1000) and ADC images (rAI ADC). The images were additionally analysed by a blinded neuroradiologist (MR).
Statistical analysis
All values are given as mean (95% CI). Between group comparisons were performed with Fisher’s exact test and Student’s t test for normally distributed data. For non-normally distributed data, the Wilcoxon test was used. Values of p<0.05 were considered significant. For assessing the inter-rater agreement, we used kappa values.
RESULTS
On DWI, 21/74 TIA patients (28%) and 10/28 TGA patients (36%) showed signal intensity changes. The time to DWI was comparable in both groups. In TGA patients, all the lesions were located in memory relevant structures such as the hippocampus, the gyrus parahippocampalis, and the medial temporal lobe. Fig 1 gives an example of a typical DWI lesion in the TGA group. Of the TGA patients, 17/28 (54%) reported valsalva-like activities, and 10 (36%) described extraordinary emotional stress at the beginning of symptoms. TGA patients with hyperintensive DWI lesions (TGA+) showed an increased incidence of vascular risk factors such as hypertension, hypercholesterolaemia, and smoking, an increased IMT (1.03 mm v 0.76 mm; p = 0.002),) and a higher prevalence of carotid plaques (70% v 17%, p = 0.01) compared with those without lesions (TGA–). In addition, the duration of symptoms (4.3 h v 7.2 h) and the time to DWI (26.1 h v 19.7 h) did not differ significantly between the TGA subgroups.
As expected, the vascular risk profile was different in TIA and TGA patients (table 1). The rAI b = 1000 was comparable in TIA and TGA patients, whereas the rAI ADC was significantly higher in TGA than in TIA patients (0.91 v 0.85; p = 0.001; table 1). Analysing the subgroup of TIA and TGA patients with abnormal DWI (TIA+ and TGA+), we detected com-parable risk factors in both groups. TIA patients showed a significant increased PS (7.53 mm v 4.13 mm, p = 0.02). The time to DWI was significantly shorter in TIA+ patients compared with TGA+ patients (14.6 h (95% CI 8.0 to 21.1) v 26.1 h (16.6 to 35.6); p = 0.03). The kappa value for inter-rater agreement was 0.85 (0.64 to 1.05), indicating very good reliability.
DISCUSSION
One of the hypotheses for the aetiology of TGA is transient cerebral ischaemia. In contrast to the findings in TIA patients, the results of DWI studies in TGA patients are controversial. There are several case reports describing DWI signal intensity changes in TGA patients,15–17 whereas two larger studies found no DWI abnormalities in TGA patients.3,4 In contrast, Sedlaczek et al5 previously described small parenchymal hyperintensities on DWI on day 2 in 11/11 patients with clinically identified TGA in a serial DWI study. Hence, the investigators conclude that the aetiology of TGA is a primarily ischaemic event. In our study, we observed a similar prevalence of DWI lesions in TGA and TIA patients. The different prevalence of DWI lesions in our study compared with that of Sedlaczek et al5 might be explained by a later onset of DWI lesions in TGA patients. Interestingly, in the subgroup of TGA+ patients the time to DWI was 26 h compared with 19 h in the TGA– group, which may support this argument. As we did not perform a serial DWI study, we cannot rule out the possibility that additionally DWI lesions could have been detected in later images. Owing to the comparable incidence of DWI lesions in TGA and TIA patients, we further evaluated the vascular risk profile of TGA and TIA patients, particularly of the subgroup with and without pathological DWI, in more detail. As expected, we found a lower incidence of vascular risk factors in TGA patients compared with TIA patients. Interestingly, TGA+ patients showed a higher vascular risk profile, significantly more frequent carotid atherosclerosis, and an increased IMT than did TGA– patients. These findings may support, particularly in this subgroup of TGA patients, an arterial embolic event. Nevertheless, there are several points that question an arterial ischaemic aetiology in all TGA patients: the different cardiovascular risk profile, the better long term outcome, and the low recurrence rate.9,18,19
Lewis1 pointed out that TGA might be caused by venous congestion as a consequence of a retrograde transmission of high venous pressure after valsalva-like activities. This hypothesis was confirmed by the finding of a higher incidence of a retrograde flow pattern in the internal jugular vein in TGA.20–22 Others have proposed a specific anxious personality trait in TGA patients, which might induce vasoconstriction due to hyperventilation during an emotional arousal.23 Therefore, temporary hypoperfusion either due to venous congestion or vasoconstriction due to hyperventilation might cause TGA. The increased vulnerability of the hippocampus and the venous drainage might help to explain why memory structures are first involved.22 As DWI lesions in venous infarction are more heterogeneous,24 it is conceivable that DWI lesions are underestimated in patients with venous ischaemia. Interestingly, the ADC ratio was significantly higher in TGA patients than in TIA patients. Increased diffusion does not necessary mean ischaemia, and it occurs even in multiple sclerosis and seizure. However, ADC changes seen during post-ictal DWI are complex, including generalised ADC changes, cortical hyperdensities, no major changes, and even ADC increase.25 The lesions we found in our population were all quite similar and comparable with DWI changes in TIA patients. Additionally, if the DWI lesions in our study were due to epileptic changes, it might be postulated that at least in a few TGA patients, EEG changes should occur.
Based on our data it might be speculated that transient ischaemia, either embolic or due to venous congestion in memory relevant structures, cause TGA and that the transient abnormalities in brain function might be too small to be detected in every TGA patient using DWI. In both groups, emotional distress might act as a pathogenic cofactor.
REFERENCES
Lewis SL. Aetiology of transient global amnesia. Lancet 1998;352:397–9.
Strupp M, Bruning R, Wu RH, et al. Diffusion-weighted MRI in transient global amnesia: elevated signal intensity in the left mesial temporal lobe in 7 of 10 patients. Ann Neurol 1998;43:164–70.
Gass A, Gaa J, Hirsch J, et al. Lack of evidence of acute ischemic tissue change in transient global amnesia on single-shot echo-planar diffusion-weighted MRI. Stroke 1999;30:2070–2.
Huber R, Aschoff AJ, Ludolph AC, et al. Transient global amnesia. Evidence against vascular ischemic etiology from diffusion weighted imaging. J Neurol 2002;249:1520–4.
Sedlaczek O, Hirsch J, Grips E, et al. Delayed hippocampal DWI changes are associated with transient global amnesia. Cerebrovascular Dis 2002;13 (Suppl 3) :58.
Kidwell CS, Alger JR, Di Salle F, et al. Diffusion MRI in patients with transient ischemic attacks. Stroke 1999;30:1174–80.
Rovira A, Rovira-Gols A, Pedraza S, et al. Diffusion-weighted MR imaging in the acute phase of transient ischemic attacks. AJNR Am J Neuroradiol 2002;23:77–83.
Crisostomo RA, Garcia MM, Tong DC. Detection of diffusion-weighted MRI abnormalities in patients with transient ischemic attack: correlation with clinical characteristics. Stroke 2003;34:932–7.
Hodges JR, Warlow CP. The aetiology of transient global amnesia. A case-control study of 114 cases with prospective follow-up. Brain 1990;113:639–57.
Caplan LR. Transient global amnesia. Amsterdam: Elsevier Science Publishers, 1985.
Special report from the National Institute of Neurological Disorders and Stroke. Classification of cerebrovascular diseases III. Stroke 1990;21:637–76.
Sander D, Winbeck K, Klingelhofer J, et al. Enhanced progression of early carotid atherosclerosis is related to Chlamydia pneumoniae (Taiwan acute respiratory) seropositivity. Circulation 2001;103:1390–5.
Nagai Y, Kitagawa K, Yamagami H, et al. Carotid artery intima-media thickness and plaque score for the risk assessment of stroke subtypes. Ultrasound Med Biol 2002;28:1239–43.
Winbeck K, Bruckmaier K, Etgen T, et al. Transient ischemic attack and stroke can be differentiated by analyzing early diffusion-weighted imaging signal intensity changes. Stroke 2004;35:1095–9.
Inamura T, Nakazaki K, Yasuda O, et al. (A lesion diagnosed by MRI in a case of transient global amnesia). No To Shinkei 2002;54:419–22.
Matsui M, Imamura T, Sakamoto S, et al. Transient global amnesia: increased signal intensity in the right hippocampus on diffusion-weighted magnetic resonance imaging. Neuroradiology 2002;44:235–8.
Greer DM, Schaefer PW, Schwamm LH. Unilateral temporal lobe stroke causing ischemic transient global amnesia: role for diffusion-weighted imaging in the initial evaluation. J Neuroimaging 2001;11:317–19.
Gandolfo C, Caponnetto C, Conti M, et al. Prognosis of transient global amnesia: a long-term follow-up study. Eur Neurol 1992;32:52–7.
Zorzon M, Antonutti L, Mase G, et al. Transient global amnesia and transient ischemic attack. Natural history, vascular risk factors, and associated conditions. Stroke 1995;26:1536–42.
Sander D, Winbeck K, Etgen T, et al. Disturbance of venous flow patterns in patients with transient global amnesia. Lancet 2000;356:1982–4.
Akkawi NM, Agosti C, Rozzini L, et al. Transient global amnesia and disturbance of venous flow patterns. Lancet 2001;357:957.
Maalikjy Akkawi N, Agosti C, et al. Transient global amnesia: a clinical and sonographic study. Eur Neurol 2003;49:67–71.
Pantoni L, Lamassa M, Inzitari D. Transient global amnesia: a review emphasizing pathogenic aspects. Acta Neurol Scand 2000;102:275–83.
Ducreux D, Petit-Lacour MC, Benoudiba F, et al. Diffusion-weighted imaging in a case of Wernicke encephalopathy. J Neuroradiol 2002;29:39–42.
Hufnagel A, Weber J, Marks S, et al. Brain diffusion after single seizures. Epilepsia 2003;44:54–63.(K Winbeck, T Etgen, H G v)