An Alzheimer Disease Challenge Model: 24-Hour Sleep Deprivation in Healthy Volunteers, Impact on Working Memory, and Reversal Effect of Pharmacological Intervention: A Randomized, Double-Blind, Placebo-Controlled, Crossover Study.

PURPOSE/BACKGROUND: Alzheimer disease (AD) is a public health issue because of the low number of symptomatic drugs and the difficulty to diagnose it at the prodromal stage. The need to develop new treatments and to validate sensitive tests for early diagnosis could be met by developing a challenge model reproducing cognitive impairments of AD. Therefore, we implemented a 24-hour sleep deprivation (SD) design on healthy volunteers in a randomized, double-blind, placebo-controlled, crossover study on 36 healthy volunteers. METHODS/PROCEDURE: To validate the SD model, cognitive tests were chosen to assess a transient worsening of cognitive functions after SD and a restoration under modafinil as positive control (one dose of 200 mg). Then, the same evaluations were replicated after 15 days of donepezil (5 mg/d) or memantine (10 mg/d). The working memory (WM) function was assessed by the N-back task and the rapid visual processing (RVP) task. FINDINGS/RESULTS: The accuracy of the N-back task and the reaction time of the RVP revealed the alteration of the WM with SD and its restoration with modafinil (changes in score after SD compared with baseline before SD), respectively, in the placebo group and in the modafinil group (-0.2% and +1.0% of satisfactory answers, P = 0.022; +21.3 and +1.9 milliseconds of reaction time, P = 0.025). Alzheimer disease drugs also tended to reverse this deterioration: the accuracy of the N-back task was more stable through SD (compared with -3.0% in the placebo group, respectively, in the memantine group and in the donepezil group: -1.4% and -1.6%, P = 0.027 and P = 0.092) and RVP reaction time was less impacted (compared with +41.3 milliseconds in the placebo group, respectively, in the memantine group and in the donepezil group: +16.1 and +29.3 milliseconds, P = 0.034 and P = 0.459). IMPLICATIONS/CONCLUSIONS: Our SD challenge model actually led to a worsening of WM that was moderated by both modafinil and AD drugs. To use this approach, the cognitive battery, the vulnerability of the subjects to SD, and the expected drug effect should be carefully considered.

Age-dependent impairment of spine morphology and synaptic plasticity in hippocampal CA1 neurons of a presenilin 1 transgenic mouse model of Alzheimer's disease.

Presenilin 1 (PS1) mutations are responsible for a majority of early onset familial Alzheimer's disease (FAD) cases, in part by increasing the production of Abeta peptides. However, emerging evidence suggests other possible effects of PS1 on synaptic dysfunction where PS1 might contribute to the pathology independent of Abeta. We chose to study the L286V mutation, an aggressive FAD mutation which has never been analyzed at the electrophysiological and morphological levels. In addition, we analyzed for the first time the long term effects of wild-type human PS1 overexpression. We investigated the consequences of the overexpression of either wild-type human PS1 (hPS1) or the L286V mutated PS1 variant (mutPS1) on synaptic functions by analyzing synaptic plasticity and associated spine density changes from 3 to 15 months of age. We found that mutPS1 induces a transient increase observed only in 4- to 5-month-old mutPS1 animals in NMDA receptor (NMDA-R)-mediated responses and LTP compared with hPS1 mice and nontransgenic littermates. The increase in synaptic functions is concomitant with an increase in spine density. With increasing age, however, we found that the overexpression of human wild-type PS1 progressively decreased NMDA-R-mediated synaptic transmission and LTP, without neurodegeneration. These results identify for the first time a transient increase in synaptic function associated with L286V mutated PS1 variant in an age-dependent manner. In addition, they support the view that the PS1 overexpression promotes synaptic dysfunction in an Abeta-independent manner and underline the crucial role of PS1 during both normal and pathological aging.

Age-related progressive synaptic dysfunction: the critical role of presenilin 1.

Mutations in presenilin 1 gene (PS1) account for the majority of early-onset familial Alzheimer's disease (FAD) cases. The disease is characterized by intracellular neurofibrillary tangles and extracellular amyloid fibrils composed of amyloid beta peptides (Abeta). Two successive cleavages are necessary to free the Abeta peptide from the amyloid precursor protein (APP). Gamma-secretase catalyzes the final cleavage of APP to generate Abeta peptides. PS1 is a catalytic subunit of gamma-secretase and is also involved in the cleavage of many membrane proteins. PS1 also has functional interactions with many other proteins. The use of animal models of AD has initiated the deciphering of these molecular pathways and mechanisms. Transgenic mouse models are useful to study the features of FAD and to investigate the nature of the neural-tissue changes of the disease and their evolution during aging. When expressed alone, mutations in human PS1 do not induce any detectable lesions, although they do increase Abeta peptides. This absence has led to the criticism that PS1 mouse models are not valuable for the study of AD. In this review we present how studies using PS1 transgenic mice have raised new questions related to pathological mechanisms of AD and are useful models for the study of (1) progressive cognitive decline, (2) early-occurring synaptic dysfunction, and (3) mechanisms other than amyloidogenesis that can be involved in disease pathogenesis.

Early Development of Symptomatic Drugs in AD: A Systematic Review of the Use of Biomarkers.

Pharmacological therapies currently marketed for Alzheimer's disease (AD) are only symptomatic and show limited effects in terms of clinical benefit. Thus, the development of new symptomatic drugs remains essential. However the dramatic increase in costs associated with drug development together with the poor number of emerging drugs highlights how crucial it is to accelerate the findings aiming to bringing new drugs to market. In this respect, optimization of the development process by integrating, at early stage, reliable biomarkers able to predict clinical benefit in phase III clinical trials may help. The improvement of certain techniques such as imaging and electrophysiological methods has led to a more accurate assessment of the brain's physiological impact of pharmacological treatments used to alleviate symptoms in AD patients. This review aims to gather the main findings from clinical studies where the effect of anti-dementia drugs were assessed in healthy volunteers and AD patients through one or several such biomarkers (electroencephalography (EEG), magnetic resonance imaging (MRI), positron emission tomography (PET), single-photon emission computed tomography (SPECT)). Overall, evidence presented in this review suggests that various biomarkers associated with key impairments observed in AD were sensitive to acetylcholinesterase inhibitors (AChE-I) medication and memantine with a good correlation with enhancement of cognitive performance. In most of the reviewed studies, only one kind of biomarker was used. Among these, deficits in quantitative EEG profile, P300 latency, and regional brain activity measured by either functional MRI (fMRI) during face encoding and working memory task or by PET/SPECT have been shown to be reversed by anti-dementia drugs. It is therefore suggested that a single biomarker approach would be limited and not be sufficiently predictive to extensively assess the potential of a new symptomatic drug. Hence, it appears that a combination approach with the use of a panel of biomarkers rather than a single biomarker may be more appropriate to establish a good correlation between the disease and therapeutic intervention.

Neurobehavioral and Cognitive Changes Induced by Sleep Deprivation in Healthy Volunteers.

To this day, the pharmacological treatment of Alzheimer's disease remains limited to the temporary stabilisation of cognitive decline and the reduction of neuropsychiatric symptoms. It is moreover with great difficulty to predict and select promising drug candidates in the early stages of the discovery and developmental process. In this context, scientists have developed new experimental paradigms to artificially induce transient cognitive impairments in healthy volunteers akin to those observed in Alzheimer's disease, i.e. the Cognitive Challenge Models. In the last decade, a great amount of literature on Sleep Deprivation was published which mainly focused on the consequences of sleep loss for public health. However, sleep deprivation paradigm may also be regarded as a cognitive challenge model. It is commonly accepted that sleep deprivation induces cognitive impairments related to a global decrease in vigilance, while in fact, there is a controversial approach related to the selective effects on cognitive functions. The identification and validation of cognitive challenge models in healthy volunteers are suitable in early clinical development of drugs to determine the 'hint of efficacy' of drug candidates. The present review aims at exploring in detail the methods, designs and cognitive paradigms used in non pharmacological sleep deprivation studies. Sleep deprivation can be induced by different methods. Probing the four main cognitive functions will allow identifying the extent to which different sleep deprivation designs selectively compromise executive function, working memory, episodic memory and attention. Findings will be discussed in line with cognitive processing levels that are required according to the tasks.

Translational Challenge Models in Support of Efficacy Studies: Neurobehavioral and Cognitive Changes Induced by Transcranial Magnetic Stimulation in Healthy Volunteers.

Transcranial Magnetic Stimulation (TMS) was proposed as a neurophysiological tool almost three decades ago. It now encompasses a very wide range of applications including clinical research and the treatment of psychiatric, neurologic and medical conditions such as depression, schizophrenia, addictions, post-traumatic stress disorders, pain, migraine, stroke, Alzheimer's disease, autism, multiple sclerosis and Parkinson's disease. By inducing electrical brain responses through the administration of magnetic pulses, TMS is in a unique position to painlessly modulate cortical regions and offers good spatial resolution and excellent temporal resolution, particularly when applied using single pulses. However, despite the impressive number of papers describing the use of TMS to modulate cognitive functions, the mechanisms underlying the behavioral changes observed after stimulation have not been fully identified. Here we present a review of the ability of TMS to transiently compromise brain function in humans. The primary aim was to investigate its capacity for use as a 'cognitive challenge model' in human pharmacological studies. The data reviewed include findings on executive function, attention and episodic memory. For each cognitive process, the convergent and divergent results are discussed in terms of paradigm differences and in order to define the optimal methodology for obtaining the desired effects.

Neurobehavioral and Cognitive Changes Induced by Hypoxia in Healthy Volunteers.

The early assessment of new symptomatic drugs against Alzheimer's disease remains difficult because of the lack of a predictive end-point. The use of a battery including different parameters could improve this early development. In order to test the reverse effect of symptomatic drugs in healthy volunteers, scientists have developed new experimental paradigms to artificially induce transient cognitive impairments in healthy volunteers akin to those observed in Alzheimer's disease, i.e. Cognitive Challenge Models. In this context, transient hypoxia could be a relevant Cognitive Challenge Model. The deleterious effects of hypoxia on cognition, as described in the literature, should be considered carefully since they are usually assessed with different populations that do not have the same hypoxic sensitivity. Hypoxia can be obtained by the means of two different methods: normobaric and hypobaric hypoxia. In both designs, cognitive changes can be directly modulated by the severity of hypoxic levels. The purpose of this review is to gather existing support on the application of hypoxia within different cognitive domains and to highlight the scientific interests of such a model to predict and select promising drug candidates. We aimed at reviewing in detail the methods, designs and cognitive paradigms used in non-pharmacological hypoxia studies. Probing the four main cognitive functions will allow identifying the extent to which different hypoxia designs selectively compromise cognitive functioning. For each cognitive process, the convergent and divergent results are discussed in terms of paradigm differences whereas we will focus on defining the optimal methodology for obtaining the desired effects.