Neurofibrillary pathology in Alzheimer disease with Lewy bodies: two subgroups

BACKGROUND: While NFT frequency is reportedly reduced in AD+DLB, we often encounter abundant neocortical NFTs in such cases and decided to investigate this discrepancy. OBJECTIVE: To compare neurofibrillary tangle (NFT) frequency in Alzheimer disease with concomitant dementia with Lewy bodies (AD+DLB) with NFT frequency in "pure" AD. METHODS: Neurofibrillary tangle frequency, as well as regional staging of neurofibrillary degeneration modified from Braak, was scored in 160 autopsy cases of primary dementia (80 AD+DLB cases and 80 pure AD cases). RESULTS: Neurofibrillary tangle and modified Braak scores were lower in AD+DLB, as reported previously. Yet, neocortical NFT scores assumed markedly different patterns in the 2 groups (P = .001). In pure AD, NFT scores of "frequent" were predominant: more cases exhibited frequent than moderate or sparse NFTs. In AD+DLB, the distribution of NFT scores was bimodal: NFTs were either frequent or few to absent. Neocortical NFT scores in the AD+DLB group tended to parallel the severity of other types of tau cytopathology (neuropil threads and tau-positive plaque neurites). CONCLUSIONS: Cases of AD+DLB may be divided into 2 subgroups based on the extent of neocortical neurofibrillary pathology. These findings could have implications for disease pathogenesis and treatment.     

Severity of cognitive impairment and the clinical diagnosis of AD with Lewy bodies

OBJECTIVE: 1) To examine the clinical differences between AD and AD with Lewy bodies (AD+LB); and 2) to determine the accuracy of Consensus guidelines for the clinical diagnosis of dementia with Lewy bodies (DLB) at different levels of dementia severity. METHODS: The authors examined the clinical characteristics of 185 patients with pathologically diagnosed AD alone and 60 with AD+LB. The relationship between clinical symptoms and AD+LB was determined by multivariate analyses, controlled by age, duration of symptoms, presence of cerebrovascular disease, and dementia severity. RESULTS: Mild dementia syndrome: No specific clinical symptom was associated with the presence of AD+LB. The sensitivity of the diagnosis of DLB was 62% and specificity was 54%. Moderate dementia syndrome: Extrapyramidal signs (EPS), especially cogwheel rigidity, and major depression were associated with AD+LB. The sensitivity for DLB was 82% and specificity was 31%. Severe dementia syndrome: Cogwheel rigidity and diurnal hypersomnia were associated with AD+LB. The sensitivity for DLB was 93% and specificity was 16%. CONCLUSIONS: The presence of EPS is not useful in differentiating AD+LB from AD in patients with mild dementia. However, as the disease progressed, they emerge as defining features, especially cogwheel rigidity. The accuracy of AD+LB diagnosis varies according the severity of the dementia syndrome. The low sensitivity and specificity in AD+LB patients with mild dementia suggest that in early stages AD+LB patients do not present the clinical characteristics of DLB. By contrast, the high sensitivity and low specificity for the diagnosis of DLB in moderate/severe dementia stages suggests that AD patients can also have characteristic symptoms of DLB. These results indicate that the antemortem diagnosis of AD+LB is difficult in all dementia stages, and better clinical and biologic differentiations of these entities are needed.     

Cortical Lewy body pathology in the diagnosis of dementia

Dementia with Lewy bodies (DLB) and Parkinson's disease (PD) are distinguishable clinically but often not neuropathologically. This study aims to test whether the distribution of cortical Lewy bodies differs in these clinicopathological groups and to develop diagnostic protocols for their differentiation. Brains were obtained at autopsy from cases recruited from prospective clinical studies of dementia or movement disorders. All cases with significant pathologies other than Lewy bodies or plaques were excluded. Cases were categorised into either PD without dementia, DLB (dementia first or within 2 years of disease onset), or PD with a later onset of dementia (PDD). The distribution and density of Lewy bodies and Lewy neurites was determined using antibodies to ubiquitin and alpha-synuclein. Cortical Lewy body densities could not separate cases of DLB from those with PDD. However, semiquantitative thresholds in the parahippocampus could separate demented from non-demented cases with high sensitivity and specificity. Interactions between multiple pathologies were determined using factor analysis. Although many cases had CA2 Lewy neurites, this was not associated with severity or duration of either dementia or parkinsonism. Most DLB cases had significant plaque pathology, and severity and duration of dementia was related to both increasing parahippocampal Lewy body densities and neuritic plaque grade. Weighted kappa statistics revealed that the combination of these pathologies indicated a more severe dementia. These results suggest that dual pathologies cause DLB, and high densities of parahippocampal Lewy bodies indicate dementia regardless of additional pathologies.     

Lewy body variant of Alzheimer’s disease or cerebral type Lewy body disease? Two autopsy cases of presenile onset with minimal involvement of the brainstem

Lewy bodies (LB) usually extend from the brainstem to the cerebrum in patients with Parkinson’s disease. However, whether the patterns of progression of LB and neuronal loss in Parkinson’s disease are identical to those in other Lewy body diseases (LBD) remains unclear. In addition, pathological data on the autonomic nervous system involvement in LBD are limited. We present here the clinicopathological characteristics of two autopsy cases with both Alzheimer’s disease and dementia with Lewy bodies (DLB), possibly diagnosed as having Lewy body variant of Alzheimer’s disease (LBV/AD). Our patients presented clinically with dementia without parkinsonism. Histopathologically, phosphorylated α‐synuclein‐positive LB and Lewy neurites were abundant in the limbic system, especially in the amygdala, and to a lesser degree, in the neocortex, including the primary motor cortex. The amygdala was also most severely affected by neuronal loss, and the other limbic areas and neocortex were affected to a lesser degree. Despite the existence of a small number of LB and many Lewy neurites, neurons in the brainstem nuclei were relatively well preserved. The Braak stages of concurrent neurofibrillary changes and senile plaques were stage V and C, respectively, in both cases. Tyrosine hydroxylase‐positive nerve fibers were relatively well spared in one case examined compared with Parkinson’s disease cases. Furthermore, many Lewy neurites immunopositive for phosphorylated α‐synuclein were found in the nerve fascicles of the epicardium in one case examined and in Parkinson’s disease cases to a lesser degree. These findings suggest that: (i) in at least some LBV/AD cases, the amygdala develops neuronal loss and Lewy‐related pathology prior to the brainstem nuclei; and (ii) the depletion of nerves in the heart tissue of LBV/AD is not necessarily complete despite the development of Lewy‐related pathology.     

Cortical inflammation in Alzheimer disease but not dementia with Lewy bodies

BACKGROUND: There have been no previous studies on the role of inflammation in the brain for the second most common dementing disorder, dementia with Lewy bodies. OBJECTIVE: To investigate the degree of cortical inflammation in dementia with Lewy bodies (DLB) compared with Alzheimer disease (AD) and control brains. DESIGN AND MAIN OUTCOME MEASURES: Post-mortem tissue collection from a brain donor program using standardized diagnostic criteria. Brains collected from January 1, 1993, through December 31, 1996, were screened and selected only for the presence or absence of tau neuritic plaques. Results of immunohistochemistry for HLA-DR were quantified using area fraction counts. Counts were performed by investigators who were unaware of the diagnosis. Results were compared across groups using analysis of variance and posthoc testing. SETTING: A medical research institute in Sydney, Australia. PATIENTS: Eight brains with DLB and without the tau neuritic plaques typical of AD, 10 brains with AD and no Lewy bodies, and 11 nondemented controls without significant neuropathological features were selected from a consecutive sample. RESULTS: Compared with AD, DLB demonstrated significantly less inflammation in the form of HLA-DR-reactive microglia in all cortical regions (P<.001, posthoc). The level of inflammation in DLB was comparable to that seen in controls (P=.54, post hoc). CONCLUSIONS: Inflammation appears related to the tau neuritic plaques of AD. Despite similar clinical presentations, therapeutic anti-inflammatory strategies are not likely to be effective for pure DLB. Arch Neurol. 2000.     

Rapid eye movement sleep behavior disorder and subtypes in autopsy-confirmed dementia with Lewy bodies

The purpose of this study was to determine whether dementia with Lewy bodies with and without probable rapid eye movement sleep behavior disorder differ clinically or pathologically. Patients with dementia with Lewy bodies (DLB) with probable rapid eye movement sleep behavior sleep disorder (n = 71) were compared with those without it (n = 19) on demographics, clinical variables (core features of dementia with Lewy bodies, dementia duration, rate of cognitive/motor changes), and pathologic indices (Lewy body distribution, neuritic plaque score, Braak neurofibrillary tangle stage). Individuals with probable rapid eye movement sleep behavior disorder were predominantly male (82% vs 47%) and had a shorter duration of dementia (mean, 8 vs 10 years), earlier onset of parkinsonism (mean, 2 vs 5 years), and earlier onset of visual hallucinations (mean, 3 vs 6 years). These patients also had a lower Braak neurofibrillary tangle stage (stage IV vs stage VI) and lower neuritic plaque scores (18% vs 85% frequency), but no difference in Lewy body distribution. When probable rapid eye movement sleep behavior disorder developed early (at or before dementia onset), the onset of parkinsonism and hallucinations was earlier and Braak neurofibrillary tangle stage was lower compared with those who developed the sleep disorder after dementia onset. Women with autopsy-confirmed DLB without a history of dream enactment behavior during sleep had a later onset of hallucinations and parkinsonism and a higher Braak NFT stage. Probable rapid eye movement sleep behavior disorder is associated with distinct clinical and pathologic characteristics of dementia with Lewy bodies.     

Clinical and pathologic features of two groups of patients with dementia with Lewy bodies: effect of coexisting Alzheimer-type lesion load

The objectives of this study were to examine the clinical and pathologic features of two subgroups of patients with dementia with Lewy bodies (DLB) differing in Alzheimer disease (AD)-type pathology load and to identify clinical variables useful in the differential diagnosis from AD. The records of 64 consecutive demented patients were reviewed. Pathologic diagnoses were independently established [35 AD cases, 11 cases of pure dementia with Lewy bodies (pDLB), and 18 cases of combined AD plus Lewy bodies (AD+LB)], and several neurodegenerative lesions were quantified. Clinical and pathologic data were compared between groups with univariate and multivariate analyses. Compared with the other groups, pDLB cases had more frequent acute-subacute onset of dementia [45% vs. AD (3%) and AD+LB (16%)], early parkinsonism [45% vs. AD (0%) and AD+LB (0%)], early [27% vs. AD (0%) and AD+LB (0%)] and late [73% vs. AD (11%) and AD+LB (16%)] hallucinations, fluctuating course [46% vs. AD (9%) and AD+LB (22%)], delusions [45% vs. AD (11%) and AD+LB (6%)], spontaneous parkinsonism [63% vs. AD (8%) and AD+LB (16%)], less frequent ideomotor apraxia and loss of insight, earlier urinary incontinence [3.2 +/- 1.4 years after onset vs. AD (6.3 years) and AD+LB (5.8 years)], shorter duration of dementia [7.7 +/- 2.4 years vs. AD (9.6 years) and AD+LB (11 years)], milder atrophy in computed tomography scans, greater brain weight, more transcortical spongiosis, wider cortex and subcortex, and less amyloid angiopathy. All pDLB cases but no AD cases had abnormal CA2 neurites. The clinical features of AD+LB patients were similar to those of AD patients other than more frequent acute-subacute onset and fluctuating evolution. Discriminant analyses selected four clinical variables differentiating pDLB from the other two groups as a whole: acute-subacute onset, early parkinsonism, early hallucinations, and early onset of urinary incontinence. Two or more of these features identified pDLB with a sensitivity of 81.8% and a specificity of 95.9%. Differentiation between the three groups (pDLB, AD+LB, and AD) or between both groups with LB (DLB) from AD could be only attained in 70% of cases. We conclude that early symptomatology is the main clue for the diagnosis of pDLB. We identified by discriminant analysis a set of clinical diagnostic criteria similar to those proposed by the Consortium on Dementia With Lewy Bodies. Accuracy was excellent for the diagnosis of pDLB but only mediocre for separating AD+LB as well as the entire DLB group from AD.     

Clinicopathologic correlates in temporal cortex in dementia with Lewy bodies

OBJECTIVE: To address the relationship between dementia and neuropathologic findings in dementia with Lewy bodies (DLB) in comparison with AD. METHODS: We evaluated the clinical presentation of autopsy-confirmed DLB in comparison with AD according to new Consortium on DLB criteria and compared the two conditions using quantitative neuropathologic techniques. This clinicopathologic series included 81 individuals with AD, 20 with DLB (7 "pure" DLB and 13 "DLB/AD"), and 33 controls. We counted number of LB, neurons, senile plaques (SP), and neurofibrillary tangles (NFT) in a high order association cortex, the superior temporal sulcus (STS), using stereologic counting techniques. RESULTS: The sensitivity and specificity of Consortium on DLB clinical criteria in this series for dementia, hallucinations, and parkinsonism are 53% and 83%, respectively, at the patient's initial visit and 90% and 68%, respectively, if data from all clinic visits are considered. In pathologically confirmed DLB brains, LB formation in an association cortical area does not significantly correlate with duration of illness, neuronal loss, or concomitant AD-type pathology. Unlike AD, there is no significant neuronal loss in the STS of DLB brains unless there is concomitant AD pathology (neuritic SP and NFT). CONCLUSIONS: The evaluation of new Consortium on DLB criteria in this series highlights their utility and applicability in clinicopathologic studies but suggests that sensitivity and specificity, especially at the time of the first clinical evaluation, are modest. The lack of a relationship of LB formation to the amount of Alzheimer-type changes in this series suggests that DLB is a distinct pathology rather than a variant of AD.     

Deposition of beta-amyloid subtypes 40 and 42 differentiates dementia with Lewy bodies from Alzheimer disease.

BACKGROUND: Alterations in the metabolism of the amyloid precursor protein and the formation of beta-amyloid (Abeta) plaques are associated with neuronal death in Alzheimer disease (AD). The plaque subtype Abeta(x-42) occurs as an early event, with Abeta(x-40) plaques forming at a later stage. In dementia with Lewy bodies (DLB), an increase in the amount of cortical Abeta occurs without severe cortical neuronal losses. OBJECTIVE: To advance our understanding of the natural history of Abeta in neurodegenerative diseases. DESIGN: We evaluated the expression of Abeta(x-40) and Abeta(x-42) in DLB using monoclonal antibodies and immunohistochemical techniques in 5 brain regions. The data were compared with those elicited with normal aging and from patients with AD. SETTING AND PATIENTS: A postmortem study involving 19 patients with DLB without concurrent neuritic degeneration, 10 patients with AD, and 17 aged persons without dementia for control subjects. RESULTS: The Abeta plaques were more numerous in patients with DLB than in controls in most brain regions, although the Abeta(x-42) plaque subtype was predominant in both conditions. Overall, Abeta(x-42) plaque density was similar in patients with DLB and those with AD, but Abeta(x-40) plaques were more numerous in persons with AD than in those with DLB. The ratio of Abeta(x-40) to Abeta(x-42) plaques was significantly reduced in persons with DLB compared with patients with AD. CONCLUSIONS: The Abeta plaques were more numerous in patients with DLB than persons with normal aging, but the plaque subtypes were similar. The relative proportion of the 2 Abeta plaque subtypes in DLB is distinguishable from that in AD.     

Lewy body pathology in Alzheimer’s disease

Lewy bodies, the characteristic pathological lesion of substantia nigra neurons in Parkinson's disease (PD), are frequently observed to accompany the amyloid plaque and neurofibrillary tangle pathology of Alzheimer's disease (AD). However the typical anatomic distribution of Lewy bodies in AD is distinct from PD. The most common site of occurrence is the amygdala, where Lewy bodies are observed in approximately 60% of both sporadic and familial AD. Other common sites of occurrence include the periamygdaloid and entorhinal cortex, while neocortical and brainstem areas develop Lewy bodies in a lower percentage of cases. In contrast, dementia with Lewy bodies (DLB), defined by widespread neocortical and brainstem Lewy bodies but frequently accompanied by variable levels of AD-type pathology, represents the other end of a spectrum of pathology associated with dementia. The observation of Lewy bodies in familial AD cases suggests that like neurofibrillary tangles, the formation of Lewy bodies can be induced by the pathological state caused by Abeta-amyloid overproduction. The role of Lewy body formation in the dysfunction and degeneration of neurons remains unclear. The protein alpha-synuclein appears to be an important structural component of Lewy bodies, an observation spurred by the discovery of point mutations in the alpha-synuclein gene linked to rare cases of autosomal dominant PD. Further investigation of alpha-synuclein and its relationship to pathological conditions promoting Lewy body formation in AD, PD, and DLB may yield further insight into pathogenesis of these diseases.     

Correlation of nicotinic receptor binding with clinical and neuropathological changes in Alzheimer's disease and dementia with Lewy bodies

Summary. We investigated the relationship between the loss of nicotinic acetylcholine receptors (nAChR) and the cognitive decline or neuropathological changes seen in Alzheimer's Disease (AD) and dementia with Lewy bodies (DLB). Midfrontal (MF) cortex of 31 AD, 24 DLB and 11 nondemented controls was examined. Total plaque (TP), neuritic plaque (NP) and neurofibrillary tangle (NFT) counts were obtained. NAChR binding was assayed using ³H-epibatidine [³H-EPI]. Last Blessed Information-Memory-Concentration scores (BIMC), Mini-Mental State Examination (MMSE), Mattis Dementia Rating Scale (DRS) scores were collected. There were no correlations between ³H-EPI binding and TP, NP, NFTs counts in either AD or DLB. Last BIMC, MMSE, DRS scores did not correlate with ³H-EPI binding in AD or DLB. Thus, decline in cognitive function does not correlate with loss of nAChR in DLB or AD at the end of life suggesting that later in these diseases, loss of nAChR binding is not a reliable marker of cognitive function in AD or DLB. Loss of nAChR activity does not appear to be related to plaques or NFTs in AD or DLB. Received March 25, 2001; accepted June 6, 2001     

Dementia with Lewy bodies

The advent of new immunostains have improved the ability to detect limbic and cortical Lewy bodies, and it is evident that dementia with Lewy bodies (DLB) is the second most common neurodegenerative dementia, after Alzheimer's disease (AD). Distinguishing DLB from AD has important implications for treatment, in terms of substances that may worsen symptoms and those that may improve them. Neurocognitive patterns, psychiatric features, extrapyramidal signs, and sleep disturbance are helpful in differentiating DLB from AD early in the disease course. Differences in the severity of cholinergic depletion and type/distribution of neuropathology contribute to these clinical differences.     

Prevalence and impact of vascular and Alzheimer pathologies in Lewy body disease

Whereas the prevalence and impact of vascular pathology in Alzheimer diease (AD) are well established, the role of vascular and Alzheimer pathologies in the progression of neurodegeneration and cognitive impairment in Parkinson disease (PD) is under discussion. A retrospective clinico-pathologic study of 100 patients with autopsy proven PD (including 44 cases with dementia/PDD) and 20 cases of dementia with Lewy bodies (DLB) confirmed essential clinical (duration of illness, Mini-Mental State Examination/MMSE, age at death) and morphologic differences between these groups; Lewy body Braak scores and Alzheimer pathologies (neuritic Braak stage, cortical Aβ plaque load, and generalized cerebral amyloid angiopathy or CAA) were significantly higher/more severe in DLB and PDD than in PD without dementia. Duration of illness showed no association to any of the examined pathologic parameters, while there was a moderate association between LB scores and neuritic Braak stages, the latter significantly increasing with age. Significant association between cerebrovascular lesions and neuritic Braak stage was seen in PDD but not in PD subjects without dementia. These data suggest an influence of Alzheimer-related lesions on the progression of the neurodegenerative process and, in particular, on cognitive decline in both PDD and DLB. On the other hand, both these factors in PD and DLB appear to be largely independent from coexistent vascular pathology, except in cases with severe cerebrovascular lesions or those related to neuritic AD pathology. Assessment of ApoE genotype in a small number of cases showed no significant differences in the severity of Aβ plaque load and CAA except for much lower intensities in non-demented ε3/3 patients. Despite increasing evidence suggesting synergistic reactions between α-synuclein (αSyn), tau and Aβ-peptides, the major protein markers of both AD and Lewy body diseases, and of both vascular pathology and AD, the molecular background and pathophysiological impact of these pathologies on the progression of neurodegeneration and development of cognitive decline in PD await further elucidation. Dedicated to the memory of Professor Dr. Franz Seitelberger, a pioneer of modern neuropathology and neurosciences.     

Activated microglia in dementia with Lewy bodies

To investigate the role of cerebral inflammation in dementia with Lewy bodies (DLB), activated microglial cells were quantified in postmortem brain tissue. Patients with pure DLB (LB but no AD pathology) had significantly greater numbers of cells than nondemented control subjects, but fewer than patients with either pure AD or DLB combined with AD. There was a positive correlation between the numbers of activated microglia and LB in different brain regions. This study demonstrates the presence of significant inflammation in DLB, even in the absence of AD pathology.     

Dementia with Lewy bodies and Parkinson's disease

Lewy bodies (LB) in the central nervous system are associated with several different clinical syndromes including Parkinson's disease (PD) and dementia with Lewy bodies (DLB). Long term follow up of PD patients finds up to 78% eventually develop dementia, most of these patients exhibiting fluctuating cognition and visual hallucinations similar to DLB and with extensive cortical LB at autopsy. alpha-Synuclein positive, neuritic pathology, in the putamen of DLB and Parkinson's disease dementia (PDD), may contribute to postural-instability gait difficulty, parkinsonism, diminished levodopa responsiveness and increased neuroleptic sensitivity. Cognitive and neuropsychiatric symptoms improve with cholinesterase inhibitor treatment in both patient groups. DLB and PDD should be seen as different points on a spectrum of LB disease. Distinguishing them as separate disorders may be useful in clinical practice, but may be of limited value in terms of investigating and treating the underlying neurobiology.     

Neuroleptics are associated with more severe tangle pathology in dementia with Lewy bodies

BACKGROUND: Neuroleptics are only modestly effective in dementia and associated with a range of adverse effects including cognitive decline. Effects of the drugs on molecular pathology in brain tissue from people with dementia have not been investigated. OBJECTIVES: To compare the severity of Alzheimer type pathology in matched groups of people with dementia with Lewy bodies (DLB), treated and not treated with neuroleptics. METHODS: The relationship between neuroleptics and Alzheimer-type pathology was determined in 40 (17 neuroleptic treated, 23 neuroleptic free, matched for age, disease duration and psychosis) clinically prospectively studied, autopsy diagnosed DLB patients. RESULTS: In regression analyses, taking neuroleptics was significantly associated with increased neurofibrillary tangles but not amyloid plaques in cortical areas examined. The patient characteristics and the frequencies of key psychiatric symptoms were similar in the patients taking and not taking neuroleptics. CONCLUSION: Although patients were not randomized and the results which are observed need to be interpreted cautiously, if substantiated, this is an important finding with major implications for the pharmacological management of DLB patients and highlights the need to determine the impact of neuroleptics upon tangle pathology in AD.     

Alzheimer’s disease pathology in motor cortex in dementia with Lewy bodies clinically mimicking corticobasal degeneration

We report here a 70-year-old woman whose initial clinical presentation suggested corticobasal degeneration, but autopsy revealed dementia with Lewy bodies (DLB) with severe Alzheimer’s disease (AD)-type pathology accentuated in the motor cortex, in conjunction with a high burden of both cortical and brain stem LB. Review of the literature disclosed four patients with AD whose peri-Rolandic region was particularly involved by the disease and who exhibited similar clinical and neuropathological findings as in our patient except they lacked LB. It appears that DLB if associated with severe AD-type pathology can, like some unusual cases of AD, mimic corticobasal degeneration. Received: 20 October 1998 / Revised, accepted: 15 February 1999     

Lewy body-related alpha-synucleinopathy in aging

To clarify the significance of Lewy body (LB)-related alpha-synucleinopathy in aging, we investigated the incidence of LBs in 1,241 consecutive autopsy cases (663 males and 578 females). LB pathology was identified histologically in sections stained with hematoxylin and eosin and with anti-ubiquitin and anti-alpha-synuclein antibodies. Cases without LBs were classified as LB stage 0 (987 cases). Cases with LBs were classified as follows: LB stage I = incidental LBs (149 cases); LB stage II = LB-related degeneration without attributable clinical symptoms (47 cases); LB stage III = Parkinson disease without dementia (10 cases); LB stage IV = dementia with Lewy bodies (DLB) transitional (limbic) form (25 cases); and LB stage V = DLB neocortical form (23 cases). The average age at death was greater for those cases with LBs. There were no gender differences in the LB pathology. G842A polymorphism in the paraoxonase I gene was associated with men in LB stage II or above and suggests a gender-specific risk factor. LB stage V had higher stages of neurofibrillary tangle and senile plaque involvement and also had a higher frequency of apolipoprotein E epsilon4. Our findings indicate that LBs are associated with cognitive decline, either independently or synergistically with neurofibrillary tangles and senile plaques.     

β‐amyloid in lewy body disease is related to Alzheimer's disease‐like atrophy

The aim of this study was to investigate whether amyloid deposition is associated with Alzheimer's disease (AD)‐like cortical atrophy in Lewy body (LB) disease (LBD). Participants included 15 LBD with dementia patients (8 with dementia with Lewy bodies [DLB] and 7 with Parkinson's disease [PD] with dementia [PDD]), 13 AD patients, and 17 healthy controls. Age, gender, and Mini–Mental State Examination scores were matched between patient groups. All subjects underwent PET scans with [¹¹C]Pittsburgh Compound B to measure brain amyloid deposition as well as three‐dimensional T1‐weighted MRI. Gray‐matter volumes (GMVs) were estimated by voxel‐based morphometry. Volumes‐of‐interest analyses were also performed. Forty percent of the 15 DLB/PDD patients were amyloid positive, whereas all AD patients and none of the healthy controls were amyloid positive. Amyloid‐positive DLB/PDD and AD patients showed very similar patterns of cortical atrophy in the parahippocampal area and lateral temporal and parietal cortices, with 95.2% of cortical atrophy distribution being overlapped. In contrast, amyloid‐negative DLB/PDD patients had no significant cortical atrophy. Compared to healthy controls, parahippocampal GMVs were reduced by 26% in both the amyloid‐positive DLB/PDD and AD groups and by 10% in the amyloid‐negative DLB/PDD group. The results suggest that amyloid deposition is associated with AD‐like atrophy in DLB/PDD patients. Early intervention against amyloid may prevent or delay AD‐like atrophy in DLB/PDD patients with amyloid deposition. © 2012 Movement Disorder Society     

Familial dementia with Lewy bodies: clinicopathologic analysis of two kindreds

Familial cases of dementia with Lewy bodies (DLB) are rare. The authors describe two small kindreds with familial DLB: one with pure DLB meeting consensus criteria for DLB and one with coexistent AD pathology that did not fulfill DLB criteria. The authors call attention to the diverse features of DLB and suggest that current clinical criteria may not detect all cases. Familial DLB is clinically heterogeneous and occurs with or without coexistent AD, suggesting the relevance of LB pathology for the developing dementia.