Drugs and vascular dementia

Impaired cognition and attention in adults: pharmacological management strategies

Cognitive psychology has provided clinicians with specific tools for analyzing the processes of cognition (memory, language) and executive functions (attention-concentration, abstract reasoning, planning). Neuropsychology, coupled with the neurosciences (including neuroimaging techniques), has authenticated the existence of early disorders affecting the "superior or intellectual" functions of the human brain. The prevalence of cognitive and attention disorders is high in adults because all the diseases implicating the central nervous system are associated with cognitive correlates of variable intensity depending on the disease process and the age of the patient. In some pathologies, cognitive impairment can be a leading symptom such as in schizophrenia, posttraumatic stress disorder or an emblematic stigmata as in dementia including Alzheimer's disease. Paradoxically, public health authorities have only recognized as medications for improving cognitive symptoms those with proven efficacy in the symptomatic treatment of patients with Alzheimer's disease; the other cognitive impairments are relegated to the orphanage of syndromes and symptoms dispossessed of medication. The purpose of this review is to promote a true "pharmacology of cognition" based on the recent knowledge in neurosciences. Data from adult human beings, mainly concerning memory, language, and attention processes, will be reported. "Drug therapeutic strategies" for improving cognition (except for memory function) are currently rather scarce, but promising perspectives for a new neurobiological approach to cognitive pharmacology will be highlighted.

The anti-dementia drugs: myth, hype or reality?

The neurodegenerative diseases are in need of drugs that are capable of treating their many different presentations. Some drugs have recently been developed and approved by the authorities for use in Alzheimer's disease; their beneficial effects are no longer questionable. From the discussion about what to call these drugs (anti-dementia drugs?), it is apparent that pharmacology research has veered from pursuing the myth of the fountain of eternal youth back to the reality of the struggle for survival of neurons whenever they are attacked, long before the signs of dementia have developed (antiapoptotic drugs?). The neurosciences teach that there is a biology of cognition (hence a pharmacology of cognition), and that the brain is the permanent area of the confrontation between neurogenesis and apoptosis. Pharmacology has taken this new understanding on board, and has finally defined its objective as preventing the decline of the neuron as much as of cognitive performance. It remains for clinicians to confirm the authenticity of this worldwide project.

Pharmacology of Alzheimer's disease: appraisal and prospects

Ten years after the introduction of the first drug, tacrine, in the treatment of Alzheimer's disease, it seems appropriate to re-appraise the pharmacological processes of innovation in the research field of dementia. The aim of this review is to pinpoint concrete improvements achieved in this field, regarding experimental methods and clinical evaluation of the compounds, as well as the neurochemistry of the disease and cellular targets to consider in priority. This review deals with this objective in three parts: (1) assessment of current therapeutics, (2) discussion of the experimental models and clinical practices and (3) prospective drugs of the future. The implementation of considered strategies will require the involvement and close cooperation between political decisions, pharmaceutical companies and the scientific community.

Clinically significant drug interactions with cholinesterase inhibitors: a guide for neurologists

Cholinesterase inhibitors are the only pharmacological class indicated for the treatment of mild to moderate Alzheimer's disease. These drugs are also being used off label to treat severe cases of Alzheimer's disease or vascular dementia and other disorders. The widespread use of cholinesterase inhibitors raises the possibility of their use in combination regimens, with the subsequent risk of deleterious drug-drug interactions in high-risk populations. The purpose of this review is to present the possible sources of pharmacokinetic or pharmacodynamic drug-drug interactions involving cholinesterase inhibitors. The four cholinesterase inhibitors (tacrine, donepezil, rivastigmine and galantamine) that are currently available have different pharmacological properties that expose patients to the risk of several types of drug interactions of nonequivalent clinical relevance. The principal proven clinically relevant drug interactions involve tacrine and drugs metabolised by the cytochrome P450 (CYP) 1A2 enzyme, as well as tacrine or donepezil and antipsychotics (which results in the appearance of parkinsonian symptoms). The bioavailability of galantamine is increased by coadministration with paroxetine, ketoconazole and erythromycin. It is of interest to note that because rivastigmine is metabolised by esterases rather than CYP enzymes, unlike the other cholinesterase inhibitors, it is unlikely to be involved in pharmacokinetic drug-drug interactions. Care must be taken to reduce the risk of inducing central (excitation, agitation) or peripheral (e.g. bradycardia, loss of consciousness, digestive disorders) hypercholinergic effects via drug interactions with cholinesterase inhibitors. A review of the literature does not reveal any alarming data but does highlight the need for prudent prescription, particularly when cholinesterase inhibitors are given in combination with psychotropics or antiarrhythmics. Possible interactions involving other often coprescribed antidementia agents (e.g. memantine, antioxidants, cognitive enhancers) remain an open area requiring particularly prudent use.