Animal model is an essential tool in the life sciences research, notably in understanding the pathogenesis of the diseases and for further therapeutic intervention success. Rodents have been the most frequently used a...Animal model is an essential tool in the life sciences research, notably in understanding the pathogenesis of the diseases and for further therapeutic intervention success. Rodents have been the most frequently used animals to model human disease since the establishment of gene manipulation technique. However, they remain inadequate to fully mimic the pathophysiology of human brain disease, partially due to huge differences between rodents and humans in terms of anatomy, brain function, and social behaviors. Nonhuman primates are more suitable in translational perspective. Thus, genetically modified animals have been generated to investigate neurologic and psychiatric disorders. The classical transgenesis technique is not efficient in that model; so, viral vector-mediated transgene delivery and the new genome-editing technologies have been promoted. In this review, we summarize some of the technical progress in the generation of an ad hoc animal model of brain diseases by gene delivery and real transgenic nonhuman primate.展开更多
Background: The brain bioavailability of novel small molecules developed to address central nervous system disease is classically documented through ex vivo or in vivo analyses conducted in rodent models. Data acquire...Background: The brain bioavailability of novel small molecules developed to address central nervous system disease is classically documented through ex vivo or in vivo analyses conducted in rodent models. Data acquired in rodent models are, however,not easily transferrable to human as the pharmacokinetic and pharmacodynamics profiles of the species are quite different.Methods: Using drugs selected for their differential transport across the blood-brain barrier, we here demonstrate the feasibility of brain microdialysis in normal vigil macaque monkey by measuring brain extracellular fluid bioavailability of carbamazepine, digoxin, oxycodone, and quinidine.Results: All drugs, but digoxin, were found in dialysate samples. Drugs that are substrate of P-glycoprotein show a difference of bioavailability or brain pharmacokinetic parameters between rodents and primates.Conclusion: Data suggest that brain microdialysis in vigil macaque monkey, the species of choice for classic pharmacokinetic/pharmacodynamics studies could help predicting human brain bioavailability of a small molecule depending on the protein involved in the efflux transport from the brain.展开更多
Depression is a frequent comorbid syndrome in Parkinson's disease. It is a difficult symptom to manage, as patients continuously receive antiparkinsonian medication and may also have to be treated for the ameliora...Depression is a frequent comorbid syndrome in Parkinson's disease. It is a difficult symptom to manage, as patients continuously receive antiparkinsonian medication and may also have to be treated for the amelioration of the side-effects of antiparkinsonian therapy. The first-line treatment for depression in Parkinson's disease is the use of selective serotonin reuptake inhibitors(SSRIs). The clinical efficacy of these medications in patients with Parkinson's disease is questionable. In fact, based on their mechanism of action, which requires at least a functional serotonergic system, it is predicted that SSRIs will have lower efficacy in patients with Parkinson's disease. Here, we consider the mechanism of action of SSRIs in the context of Parkinson's disease by investigating the fall in the levels of serotonergic markers and the inhibitory outcomes of antiparkinsonian treatment on serotonergic nerve activity. Because certain classes of antidepressant drugs are widely available, it is necessary to perform translational research to address different strategies used to manage depression in Parkinson's disease.展开更多
文摘Animal model is an essential tool in the life sciences research, notably in understanding the pathogenesis of the diseases and for further therapeutic intervention success. Rodents have been the most frequently used animals to model human disease since the establishment of gene manipulation technique. However, they remain inadequate to fully mimic the pathophysiology of human brain disease, partially due to huge differences between rodents and humans in terms of anatomy, brain function, and social behaviors. Nonhuman primates are more suitable in translational perspective. Thus, genetically modified animals have been generated to investigate neurologic and psychiatric disorders. The classical transgenesis technique is not efficient in that model; so, viral vector-mediated transgene delivery and the new genome-editing technologies have been promoted. In this review, we summarize some of the technical progress in the generation of an ad hoc animal model of brain diseases by gene delivery and real transgenic nonhuman primate.
文摘Background: The brain bioavailability of novel small molecules developed to address central nervous system disease is classically documented through ex vivo or in vivo analyses conducted in rodent models. Data acquired in rodent models are, however,not easily transferrable to human as the pharmacokinetic and pharmacodynamics profiles of the species are quite different.Methods: Using drugs selected for their differential transport across the blood-brain barrier, we here demonstrate the feasibility of brain microdialysis in normal vigil macaque monkey by measuring brain extracellular fluid bioavailability of carbamazepine, digoxin, oxycodone, and quinidine.Results: All drugs, but digoxin, were found in dialysate samples. Drugs that are substrate of P-glycoprotein show a difference of bioavailability or brain pharmacokinetic parameters between rodents and primates.Conclusion: Data suggest that brain microdialysis in vigil macaque monkey, the species of choice for classic pharmacokinetic/pharmacodynamics studies could help predicting human brain bioavailability of a small molecule depending on the protein involved in the efflux transport from the brain.
基金Supported by"Centre National de la Recherche Scientifique"and the"conseil Régional d’Aquitaine"
文摘Depression is a frequent comorbid syndrome in Parkinson's disease. It is a difficult symptom to manage, as patients continuously receive antiparkinsonian medication and may also have to be treated for the amelioration of the side-effects of antiparkinsonian therapy. The first-line treatment for depression in Parkinson's disease is the use of selective serotonin reuptake inhibitors(SSRIs). The clinical efficacy of these medications in patients with Parkinson's disease is questionable. In fact, based on their mechanism of action, which requires at least a functional serotonergic system, it is predicted that SSRIs will have lower efficacy in patients with Parkinson's disease. Here, we consider the mechanism of action of SSRIs in the context of Parkinson's disease by investigating the fall in the levels of serotonergic markers and the inhibitory outcomes of antiparkinsonian treatment on serotonergic nerve activity. Because certain classes of antidepressant drugs are widely available, it is necessary to perform translational research to address different strategies used to manage depression in Parkinson's disease.
