Abstract
IntroductionA substantial number of therapeutic drugs for Alzheimer's disease (AD) have failed in late-stage trials, highlighting the translational disconnect with pathology-based animal models.MethodsTo bridge the gap between preclinical animal models and clinical outcomes, we implemented a conductance-based computational model of cortical circuitry to simulate working memory as a measure for cognitive function. The model was initially calibrated using preclinical data on receptor pharmacology of catecholamine and cholinergic neurotransmitters. The pathology of AD was subsequently implemented as synaptic and neuronal loss and a decrease in cholinergic tone. The model was further calibrated with clinical Alzheimer's Disease Assessment Scale-cognitive subscale (ADAS-Cog) results on acetylcholinesterase inhibitors and 5-HT6 antagonists to improve the model's prediction of clinical outcomes.ResultsAs an independent validation, we reproduced clinical data for apolipoprotein E (APOE) genotypes showing that the ApoE4 genotype reduces the network performance much more in mild cognitive impairment conditions than at later stages of AD pathology. We then demonstrated the differential effect of memantine, an N-Methyl-D-aspartic acid (NMDA) subunit selective weak inhibitor, in early and late AD pathology, and show that inhibition of the NMDA receptor NR2C/NR2D subunits located on inhibitory interneurons compensates for the greater excitatory decline observed with pathology.ConclusionsThis quantitative systems pharmacology approach is shown to be complementary to traditional animal models, with the potential to assess potential off-target effects, the consequences of pharmacologically active human metabolites, the effect of comedications, and the impact of a small number of well described genotypes.
Highlights
A substantial number of therapeutic drugs for Alzheimer’s disease (AD) have failed in late-stage trials, highlighting the translational disconnect with pathology-based animal models
Our extensions of the model are to (1) implement the physiology of a number of neuromodulatory receptors based upon preclinical physiology, (2) increase the size of the network to 80 pyramidal cells and 40 inhibitory interneurons to accommodate higher resolution for the AD pathology, (3) reduce the relative fraction of inhibitory synapses according to recent neuroanatomical data, (4) implement the pathology of Alzheimer’s disease based upon human pathology data and (5) calibrate the remaining biological coupling model parameters using the correlation between the effects of therapeutic interventions and genotypes in the model and the reported ADAS-Cog clinical effects
The model includes the physiology of the dopamine D1, D2 and D4 receptors, the serotonin 5HT1A, 5-HT2A, 5-HT3, 5-HT4 and 5-HT6 receptors, the adrenergic a2A receptor and cholinergic M1, M2 Muscarinic acetylcholine receptor mild cognitive impairment (MCI) (mACh-R), and a7 and a4b2 nicotinic ACh receptor (nACh-R), whereas the pharmacology of 5-HT6 antagonism includes increases of glutamate and acetylcholine in the cortex
Summary
A substantial number of therapeutic drugs for Alzheimer’s disease (AD) have failed in late-stage trials, highlighting the translational disconnect with pathology-based animal models. Different treatment strategies may be necessary to compensate for changing bio-logical conditions. Unless specific biomarkers are available to directly measure progression of the disease, we must rely on indirect functional indicators to signal the progress. For complex diseases such as Alzheimer’s disease (AD), biophysical modeling can provide an important tool [1] to link indirect functional. Many experimental therapeutics in AD are based on disease-modifying strategies, yet the ultimate clinical test is functional. The only approved medications for AD are based on the cholinergic system [2], and specific muscarinic [3] and nicotinic targets [4] are currently under investigation. Other symptomatic interventions under investigation include serotonergic targets, such as 5-HT4[5] and a 5-HT6
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