An article in Nature Reviews Drug Discovery (Nature Rev. Drug Discov. 11, 657–660; 2012)1 reported that three prevention trials (known as API, DIAN and A4) in patients with asymptomatic Alzheimer’s disease (AD) hope, with biomarker and cognitive changes, to validate the amyloid hypothesis and set the stage for AD drug approvals. A response (Nature Rev. Drug Discov. 12, 324; 2013)2 endorsed the plans in this earlier report.
Here, we question the wisdom of this step for these trials and another proposed study (known as DSBI) (TABLE 1). As currently designed, we consider that AD drug development trials have four important deficiencies. First, without the addition of aims to test specific mechanistic hypotheses that are able to explain the conditions necessary to modify the course of AD, these clinical trials will not advance our knowledge of AD neuropathologies and their roles in progression to symptomatic AD. Second, knowledge of how the timing of neuropathologies may affect the successful use of agents that target the 42-amino-acid form of the amyloid-β peptide (Aβ42) or other AD drugs will not advance. Third, a potentially useful drug may be abandoned owing to lack of clinical efficacy. Fourth, drug effects on symptoms may be misinterpreted as evidence for disease modification.
Table 1.
Selected trials of amyloid-β (Aβ)-targeted interventions for Alzheimer’s disease (AD)*
| Sponsoring group |
Subjects (number proposed) |
Special conditions |
Rationale for subject selection |
Drug intervention |
Trial duration |
Outcome variable(s) |
|---|---|---|---|---|---|---|
| Alzheimer’s Prevention Initiative (API)9,10 |
Asymptomatic subjects with mutations in PS1 (100 drug; 100 placebo) |
PS1-positive subjects within 10 years before apparent cognitive decline |
Excess Aβ42 levels predispose to early-onset AD |
Crenezumab | 5 years | PET-fibrillar Aβ, PET-FDG, structural MRI and clinical end point biomarkers accepted as indicators of AD progression and an untested composite of five cognitive tests not specified9,10 |
|
| ||||||
| Dominantly Inherited Alzheimer Network (DIAN)6 |
Asymptomatic subjects at-risk for familial AD (mutations in APP, PS1 and PS2) (160) |
Subjects within 15 years of predicted AD onset |
Confirmed family pedigree for autosomal dominant AD |
Solanezumab and gantenerumab |
5 years | Neuropathological biomarkers to validate target effects of drug interventions and an undisclosed cognitive end point6 |
|
| ||||||
| Anti-amyloid treatment in asymptomatic AD (A4)11 |
Elderly asymptomatic and symptomatic subjects (500 drug; 500 placebo) |
Subjects positive for brain amyloid with PET imaging |
Drug intervention prior to irreversible neuropathological damage to neurons |
Solanezumab | 3 years | The untested ADCS– PACC outcome includes the Free and Cued Selective Reminding Test, the Logical Memory IIa, Digit Symbol and Mini Mental State Exam8,11. |
|
| ||||||
| Down Syndrome Biomarker Initiative’ (DSBI)12 |
Subjects with Down’s syndrome (12) |
APP trisomy | Development of brain amyloid plaques and neurofibriallary tangles by age 30 years and increased lifetime risk (75%) for AD |
Not specified12 | 3 years | Not specified12 |
ADCS–PACC, Alzheimer’s Disease Cooperative Study–Preclinical Alzheimer’s Cognitive Composite; APP, amyloid precursor protein; FDG, fludeoxyglucose; MRI, magnetic resonance imaging; PET, positron emission tomography; PS, presenilin.
The concern for all of these studies (discussed in the main text) is that Aβ-induced phosphorylated-tau and/or other self-sustaining cascades may have already been initiated, and as currently designed they miss the opportunity to test these or other mechanistic hypotheses.
Background
Lack of mechanistic grounding for currently proposed AD clinical trials
There are several issues that might confound the currently proposed AD clinical trials. First, both Aβ42-related and phosphorylated-tau (p-tau)-related neuropathologies are well established a decade or more before AD is clinically diagnosed1–3. Second, concentrations in the brain of Aβ42 and its oligomers and neurofibrillary tangles correlate with — but do not predict — the severity, progression or diagnosis of dementia3,4. The planned trials initiate treatments before clinical AD onset, but without timing treatment so that it specifically targets any irreversible neuropathology that later triggers clinical dementia5. They do not exclude or investigate these issues and therefore risk starting treatment after a self-sustaining pathology is established.
Furthermore, clinical AD is associated with other disease conditions, such as cerebral amyloid angiopathy and other cerebrovascular pathologies. These or other accompanying conditions have the potential to precipitate patients with familial or sporadic AD into clinical dementia. Age, co-morbidity, vascular pathologies, insulin resistance, genetic, environmental, biochemical or cognitive reserve factors may be necessary for clinical expression of dementia. If such possibilities are not considered, the planned trials of the anti-Aβ42 drugs may be confounded, undermining their utility. For example, the patients with familial AD involved in the DIAN trial6 inevitably develop AD pathology and progress to clinical AD, which provides a unique opportunity to understand the roles of Aβ42 and self-sustaining pathologies without involving subjects who do not progress on to dementia. However, if other confounding factors are not accounted for, its utility will be compromised.
Elusive clinical efficacy
Other than immediately before and following the clinical diagnosis of mild cognitive impairment (MCI), there has been no evidence reported so far to support the ameloriation of cognitive deficits as a demonstration of clinical efficacy for proposed therapeutic interventions for AD. Indeed, emerging evidence supports the view that ‘clinically silent’ AD neuropathologies accumulate to cause clinically observable MCI and AD decades later1–3. Consequently, unless patients are followed up for 10 years or more, it seems unlikely that clinical efficacy of the anti-Aβ42 agents or other interventions being tested in currently proposed clinical trials will be seen.
In the proposed clinical trials involving asymptomatic patients, any observed cognitive changes (or lack of cognitive changes) could not be definitively ascribed to effects of the intervention on AD-relevant neuropathologies without additional evidence. For example, cognitive enhancement may occur without affecting AD-relevant neuropathologies and important neuropathological benefits may occur without cognitive effects. This could lead to erroneous decisions to claim (or not claim) effects on disease progression and to progress (or terminate) the further development of the compounds being studied.
A new roadmap
Drug development for AD has failed to significantly improve on earlier drug treatments, despite impressive advances in our understanding of the cellular and molecular biology of the disease. In our view, this is partly because clinical trials so far have focused on efficacy and not on the rigorous testing of the putative mechanisms of disease and the impact of the drugs tested on these mechanisms.
Known mechanisms that increase the levels of Aβ42 in AD include the following: increased synthesis of the amyloid precursor protein; altered β-secretase activities; and reduced clearance of Aβ42. Subjects in the API, DIAN and DSBI trials have known genetic factors that potentially affect the increased synthesis of the amyloid precursor protein and/or altered β-secretase activities. In the A4 trial, subjects predominantly have genetic or other factors affecting clearance of Aβ42. However, none of the trials are timing the drug intervention on the basis of prior investigations of the onset of possible irreversible Aβ42 accumulation or Aβ42 induction of a neuropathology critical to progression into clinical dementia. Nor are the trials designed to specifically test the different timings of possible critical Aβ42 accumulations or inductions. Because of the pathological effects of p-tau on neurons, controlling only Aβ42 concentrations even a decade or more before clinical AD may have no effect on AD progession regardless of the various factors that are thought to underlie the development of AD in the different trial populations (TABLE 1).
We propose that investigators give priority to the development of a molecular mechanistic theory for AD that will distinguish disease by the pathogenesis underlying the final common pathway to clinical AD. In addition, this theory will discriminate the specific neuropathological target or targets to be tested and how they will be tested for clinical relevance. For example, the current amyloid hypothesis of AD does not identify a specific pathogenic target or targets responsible for clinical AD, or differentiate roles for Aβ42, Aβ42 oligomers or Aβ42 amyloid concentrations and multiple other factors and the interactions among these. The amyloid hypothesis is also not able to predict the effects from drugs used to alter Aβ42 targets or define the timing of interventions. With long durations between interventions and disease onset, at least three of the currently proposed AD clinical trials — API, DIAN and DSBI — are well positioned to take on these tasks of turning AD drug development away from an overly exclusive focus on product development and onto the investigation and validation of a mechanistic theory of AD.
Consistent with this effort, and to avoid the mistaken termination of drugs for lack of clinical efficacy, we recommend that investigators in the current trials pursue evidence for mechanistic efficacy as rigorously as possible rather than overly invest in clinical efficacy as end points. Trials will be regarded as scientifically successful if they demonstrate both drug safety and, with biomarkers grounded in refined and tested AD mechanistic theory, neuropathologically significant, not merely statistically significant, reductions in pre-specified, theoretically justified, Aβ42-related or other neuropathologies. Preferred end points would be a return of the targeted neuropathology to levels found in non-at-risk AD subjects. Using biomarkers with documented mechanistic implications, currently proposed trials can test the molecular mechanisms that are able to explain both the lack of efficacy for persons at-risk of AD but still not symptomatic and the grounds for expecting the subjects to progress to clinical AD.
In summary, we suggest that for AD drug development to become more soundly scientifically grounded, researchers need to give priority to the development of a molecular theory of disease that will be systematically tested and refined in clinical trials7. AD clinical trials continue to be initiated with little or no robust data relating to the mechanism of action leading to disease progression. Most problematic, the planned trials initiate treatments prior to clinical AD onset, but without timing that specifically targets any irreversible neuropathology that later triggers clinical dementia8 . Scientifically and ethically, mechanisms of drug action are optimally identified, confirmed and characterized in preclinical studies before progressing to clinical trials. The abandonment of anti-Aβ42 drugs and pursuit of clinical efficacy for new targets will not fix the problems we discuss. As a first step we propose modifications of currently planned and future AD clinical trials to provide maximum support for the advance of theory and for continued research with compounds with potential uses as pharmacological probes of disease mechanisms or drug candidates in future AD clinical trials.
Footnotes
Competing interests statement
The authors declare competing interests: see Web version for details.
Contributor Information
Robert E. Becker, 5011 Mountain View Road #63, Carrabassett Valley, Maine O4947, USA, and a Clinical Consultant in the Drug Design and Development Section, Translational Gerontology Branch, Intramural Research Program, National Institute on Aging, National Institutes of Health, Baltimore, Maryland 21224, USA.
Nigel H. Greig, Translational Gerontology Branch, Intramural Research Program, National Institute on Aging, National Institutes of Health, Baltimore Maryland 21224, USA.
Ezio Giacobini, Department of Internal Medicine, Rehabilitation, and Geriatrics, University of Geneva, Medical School, University Hospitals of Geneva, Thonex-Geneva, Switzerland.
Lon S. Schneider, Departments of Psychiatry, Neurology, and Gerontology, Keck School of Medicine, University of Southern California, Los Angeles, California 90033, USA.
Luigi Ferrucci, National Institute on Aging, National Institutes of Health, Baltimore, Maryland 21224, USA.
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