Dept of Psychology and Program in Neuroscience, University of Arizona, Tucson, USA.
Behav Brain Funct. 2008 Jan 30;4:5. doi: 10.1186/1744-9081-4-5.
The transitive inference (TI) task assesses the ability to generalize learned knowledge to new contexts, and is thought to depend on the hippocampus (Dusek & Eichenbaum, 1997). Animals or humans learn in separate trials to choose stimulus A over B, B over C, C over D and D over E, via reinforcement feedback. Transitive responding based on the hierarchical structure A > B > C > D > E is then tested with the novel BD pair. We and others have argued that successful BD performance by animals - and even humans in some implicit studies - can be explained by simple reinforcement learning processes which do not depend critically on the hippocampus, but rather on the striatal dopamine system. We recently showed that the benzodiazepene midazolam, which is thought to disrupt hippocampal function, profoundly impaired human memory recall performance but actually enhanced implicit TI performance (Frank, O'Reilly & Curran, 2006). We posited that midazolam biased participants to recruit striatum during learning due to dysfunctional hippocampal processing, and that this change actually supported generalization of reinforcement values. Greene (2007) questions the validity of our pharmacological assumptions and argues that our conclusions are unfounded. Here we stand by our original hypothesis, which remains the most parsimonious account of the data, and is grounded by multiple lines of evidence.
传递推理 (TI) 任务评估将所学知识推广到新情境的能力,被认为依赖于海马体 (Dusek & Eichenbaum, 1997)。动物或人类通过强化反馈在单独的试验中学习选择刺激 A 而不是 B、B 而不是 C、C 而不是 D 和 D 而不是 E。然后,通过新颖的 BD 对测试基于层次结构 A > B > C > D > E 的传递反应。我们和其他人认为,动物(甚至在某些内隐研究中人类)成功的 BD 表现可以通过简单的强化学习过程来解释,这些过程并不严重依赖海马体,而是依赖纹状体多巴胺系统。我们最近表明,苯二氮䓬类药物咪达唑仑被认为会破坏海马体功能,严重损害人类记忆回忆表现,但实际上增强了内隐 TI 表现 (Frank、O'Reilly & Curran, 2006)。我们假设咪达唑仑由于海马体处理功能障碍而使参与者在学习过程中偏向于招募纹状体,并且这种变化实际上支持了强化值的泛化。Greene (2007) 质疑我们药理学假设的有效性,并认为我们的结论是没有根据的。在这里,我们坚持我们的原始假设,这仍然是对数据最简洁的解释,并得到了多条证据的支持。