Is antipsychotic sensitivity in Alzheimer’s disease secondary to abnormal blood–brain barrier integrity?

Elderly persons are more sensitive to the adverse effects of antipsychotic drugs. Thus, the need to minimize these adverse effects when treating aggression, agitation and psychosis in patients with Alzheimer’s disease has become paramount. However, scant information on pharmacokinetics (relationship between dose, systemic drug concentrations, and time) and pharmacodynamics (relationship between systemic drug concentration and the effect of the drug over time) exists to inform minimally effective antipsychotic dosing guidelines for Alzheimer’s disease. In developing such guidelines for treating behavioural symptoms, much can be drawn from psychiatry’s efforts to elucidate the mechanism of action and therapeutic window of antipsychotic drugs. In this issue of Brain, Reeves et al. build upon these efforts by using PET to determine how blood concentrations of the antipsychotic amisulpride relate to occupancy of brain dopamine D2-type (D2) receptors, and in turn, therapeutic and adverse effects in elderly patients with Alzheimer’s disease (Reeves et al., 2017). In the early 1950s chlorpromazine, with its ability to produce a ‘calm quietude’, was successfully used in the treatment of psychosis. It was not until the late 1970s that the clinical efficacy of doses of antipsychotics was found to correlate with their ability to inhibit dopamine D2 receptors in striatal membranes in vitro (Seeman et al., 1975). With the development of radio-labelled ligands that could bind to D2 receptors, it became possible to quantify the availability of D2 receptors in the living human brain using PET. Soon after, it became apparent that antipsychotics did bind to striatal D2 receptors in patients with schizophrenia in vivo, blocking the binding of D2-preferring radioligands (Farde et al., 1988). Translating the earlier ex vivo work, several PET studies suggested a ‘therapeutic window’ of striatal D2 receptor occupancy by antipsychotics; 65– 80% occupancy was associated with a positive clinical response, while occupancies above 80% were likely to induce unwanted extrapyramidal and endocrinological side-effects (Howes and Kapur, 2009). Notably, elderly patients with schizophrenia (age550) were more sensitive to extrapyramidal side effects of antipsychotic drugs, showing side effects at lower drug occupancies (580%) compared to younger patients (Graff-Guerrero et al., 2015; Iwata et al., 2016; Nakajima et al., 2016). Given that striatal D2 receptor expression and dopamine synthesis decrease with age, it was suggested that this may be due in part to pharmacodynamic changes with ageing. Using PET, efforts have been made to establish minimally effective dose-D2 receptor occupancies for elderly patients with schizophrenia, which may be closer to 50% (Graff-Guerrero et al., 2015) with an upper threshold of 66% for side-effects (Iwata et al., 2016). However, it is unknown how D2 receptor occupancy by antipsychotics relates to clinical response in elderly patients with Alzheimer’s disease. Reeves et al. are the first to attempt to elucidate this information in Alzheimer’s disease with psychosis, and provide important empirical data linking psychosis (i.e. hallucinations and delusions) with an aberrant dopaminergic state in Alzheimer’s disease. The link between psychosis and dopamine has been informed by two converging lines of evidence that support the dopamine hypothesis of schizophrenia. The first was the observation that D-amphetamine, and related compounds that enhance dopaminergic neurotransmission, elicit a psychotic state (Abi-Dargham et al., 2009). The second was the discovery that antipsychotics cause increased central monoamine turnover, and that all antipsychotics bind to D2 receptors (Carlsson and Lindqvist, 1963). Soon thereafter, it was shown that antipsychotics antagonize amphetamine-induced psychotic states, thereby linking aberrant dopamine transmission with psychotic symptoms and antipsychotic action. While the original idea of dysregulated striatal dopamine transmission in schizophrenia has been confirmed by neuroimaging studies, which show increased dopamine synthesis, increased release of dopamine in response to a challenge, and a higher level of synaptic dopamine (Howes and Kapur, 2009), the mechanism of psychosis in Alzheimer’s disease is only supported by the association between psychotic symptoms and antipsychotic action. Using population-based pharmacokinetic models in conjunction with F-fallypride PET, Reeves et al. characterize the relationship between blood concentrations of the antipsychotic amisulpuride and central D2 receptor occupancy. Notably, low average blood concentrations of amisulpride (71 30 ng/ml) were associated with high central D2 receptor occupancies in the striatum (caudate 65%; putamen 52%) and thalamus ( 67%). Importantly, a blood Scientific Commentaries BRAIN 2017: 140; 856–867 | 865