- Aggleton JP, Mishkin M (1983) Memory impairments following restricted medial thalamic lesions in monkeys. Exp Brain Res 52:199–209
Google Scholar
- Aggleton, JP, Passingham RE (1981) Stereotaxic surgery under x-ray guidance in the rhesus monkey, with special reference to the amygdala. Exp Brain Res 44:271–276
Google Scholar
- Aggleton, JP, Nicol RM, Huston AE, Fairbairn AF (1988) The performance of amnesic subjects on tests of experimental amnesia in animals: delayed matching to sample and concurrent learning. Neuropsychologia 26:272
Google Scholar
- Aigner TG, Mitchell SJ, Aggleton JP, DeLong MR, Struble RG, Price DL, Wenk GL, Mishkin M (1987) Effects of scopolamine and physostigmine on recognition memory in monkeys with ibotenic-acid lesions of the nucleus basalis of Meynert. Psycho pharmacology © Springer Verlag. 92:292–300
Google Scholar
- Baker RJ, Neider JA (1978) The GLIM (Generalised Linear Interactive Modelling) system. Royal Statistical Society (Numerical Algorithm Group, 7 Banbury Rd, Oxford)
Google Scholar
- Baylis GC, Rolls ET (1987) Responses of neurones in the inferior temporal cortex in short term and serial recognition memory tasks. Exp Brain Res 65:614–622
Google Scholar
- Baylis GC, Rolls ET, Leonard CM (1987) Functional subdivisions of the temporal lobe neocortex. J Neurosci 7:330–342
Google Scholar
- Bonin G von, Bailey P (1947) The neocortex of Macaca mulatta. University of Illinois Press, Urbana
Google Scholar
- Brown MW (1982) Effect of context on the responses of single units recorded from the hippocampal region of behaviourally trained monkeys. In: Ajmone-Marsan C, Matthies H, (eds), Neuronal plasticity and memory formation. (IBRO monograph series, vol 9) Raven, New York, pp 557–573
Google Scholar
- Brown MW (1990) Why does the cortex have a hippocampus? In: Gabriel M, Moore J (eds) Learning and computational neuroscience: foundations of adaptive networks. MIT, New York, pp 233–282
Google Scholar
- Brown J, Brown MW (1990) The effects of repeating a recognition test in lorazepam-induced amnesia: evidence for impaired contextual memory as a cause of amnesia. Q J Exp Psychol [B] 42A: 279–290
Google Scholar
- Brown MW, Leendertz JA (1979) A pulse-shape discriminator for action potentials. J Physiol (Lond) 298:17–18P
Google Scholar
- Brown MW, Wilson FAW, Riches IP (1987) Neuronal evidence that inferomedial temporal cortex is more important than hippocampus in certain processes underlying recognition memory. Brain Res 409:158–162
Google Scholar
- Brown MW, Brown J, Bowes JB (1989) Absence of priming coupled with substantially preserved recognition in lorazepam-induced amnesia. Q J Exp Psychol [B] 41A: 599–617
Google Scholar
- Fahy FL, Riches IP, Brown MW (1991) Neuronal evidence of the involvement of the primate medial thalamus in recognition memory. Eur J Neurosci [Suppl] 4:88
Google Scholar
- Fahy FL, Riches IP, Brown MW (1993) Neuronal signals of importance to the performance of visual recognition memory tasks: evidence from recordings of single neurones in the medial thalamus of primates. Prog Brain Res 95:401–416
Google Scholar
- Fuster JM, Jervey JP (1981) Inferotemporal neurons distinguish and retain behaviorally relevant features of visual stimuli. Science 212:952–955
Google Scholar
- Fuster JM, Uyeda AA (1971) Reactivity of limbic neurons of the monkey to appetitive and aversive signals. Electroencephalogr Clin Neurophysiol 30:281–293
Google Scholar
- Fuster JM, Bauer RH, Jervey JP (1981) Effects of cooling inferotemporal cortex on performance of visual memory tasks. Exp Neurol 71:398–409
Google Scholar
- Gaffan D (1974) Recognition impaired and association intact in the memory of monkeys after transection of the fornix. J Comp Physiol Psychol 80:1100–1109
Google Scholar
- Gaffan D (1992) Amnesia for complex naturalistic scenes and for objects following fornix transection in the rhesus monkey. Eur J Neurosci 4:381–388
Google Scholar
- Gaffan D, Murray EA (1992) Monkeys (Macaca fascicularis) with rhinal cortex ablations succeed in object discrimination learning despite 24-hour intertriai intervals and fail at matching to samle despite double sample presentations. Behav Neurosci 106:30–38
Google Scholar
- Heit G, Smith ME, Halgren E (1990) Neuronal activity in the human medial temporal lobe during recognition memory. Brain 113:1093–1112
Google Scholar
- Horel JA, Pytko-Joiner DE, Voytko M, Salsbury K (1987) The performance of visual tasks while segments of the inferotemporal cortex are suppressed by cold. Behav Brain Res 23:29–42
Google Scholar
- Insausti R, Amaral DG, Cowan WM (1987) The entorhinal cortex of the monkey. III. Subcortical afferents. J comp Neurol 261:396–408
Google Scholar
- Lindsey JK (1992) The analysis of stochastic processes using GLIM. Springer, Heidelberg New York Berlin
Google Scholar
- Mayes AR (1988) Human organic memory disorders. University Press, Cambridge
Google Scholar
- Mayes AR, Meudell PR, Pickering A (1985) Is organic amnesia caused by a selective deficit in remembering contextual information? Cortex 21:167–202
Google Scholar
- Miller EK, Gochin PM, Gross CG (1991a) Habituation-like decrease in the responses of neurons in inferior temporal cortex of the macaque. Vis Neurosci 7:357–362
Google Scholar
- Miller EK, Li L, Desimone R (1991b) A neuronal mechanism for working and recognition memory in inferior temporal cortex. Science 254:1377–1379
Google Scholar
- Mishkin M (1982) A memory system in the monkey. Philos Trans R Soc Lond [Biol] 298:85–95
Google Scholar
- Miyashita Y (1988) Neuronal correlate of visual associative longterm memory in the primate temporal cortex. Nature 335:817–820
Google Scholar
- Murray EA (1991) Medial temporal lobe structures contributing to recognition memory: the amygdaloid complex versus the rhinal cortex. In: Aggleton JP (eds) The amygdala: neurobiological aspects of emotion, memory and mental dysfunction. Wiley-Liss, New York, pp 453–470
Google Scholar
- Nishijo H, Ono T, Nishino H (1988) Single neuron responses in amygdala of alert monkey during complex sensory stimulation with affective significance. J Neurosci 8:3570–3583
Google Scholar
- Olton DS, Becker JT, Handelmann GE (1979) Hippocampus, space and memory. Behav Brain Sci 2:313–322
Google Scholar
- Parkin AJ (1987) Memory and amnesia: an introduction, Blackwell, Oxford
Google Scholar
- Pearson RCA, Esiri MM, Hiorns RW, Wilcock GK, Powell TPS (1985) Anatomical correlates of the distribution of the pathological changes in the neocortex in Alzheimer's disease. Proc Natl Acad Sci USA 82:4531–4534
Google Scholar
- Riches IP, Brown MW, Wilson FAW (1990) Neurones of inferomedial temporal cortex display evidence of memory for the previous occurrence of visual stimuli. Perception 19:269–270
Google Scholar
- Riches IP, Fahy FL, Brown MW (1991a) Involvement of the primate medial temporal lobe in recognition memory: neuronal evidence of long-term retention and discrimination of familiarity and recency. Eur J Neurosci [Suppl] 4:89
Google Scholar
- Riches IP, Wilson FAW, Brown MW (1991b) The effects of visual stimulation and memory on neurons of the hippocampal formation and the neighboring parahippocampal gyrus and inferior temporal cortex of the primate. J Neurosci 11:1763–1779
Google Scholar
- Rolls ET, Perrett DI, Caan AW, Wilson FAW (1982) Neuronal responses related to visual recognition. Brain 105:611–646
Google Scholar
- Rolls ET, Miyashita Y, Cahusac PMB, Kesner RP, Niki H, Feigenbaum JD, Bach L (1989) Hippocampal neurons in the monkey with activity related to the place in which a stimulus is shown. J Neurosci 9:1835–1845
CAS PubMed Google Scholar
- Seltzer B, Pandya DN (1978) Afferent cortical connections and architectonics of the superior temporal sulcus and surrounding cortex in the rhesus monkey. Brain Res 149:1–24
Google Scholar
- Shimamura AP (1986) Priming effects in amnesia: evidence for a dissociable memory function. Q J Exp Psychol [B] 38A:619–644
Google Scholar
- Squire LR (1987) Memory and brain. Oxford University Press, New York
Google Scholar
- Squire LR, Zola-Morgan S (1991) The medial temporal lobe memory system. Science 253:1380–1386
Google Scholar
- Squire LR, Zola-Morgan S, Chen KS (1988) Human amnesia and animal models of amnesia: performance of amnesic patients on tests designed for the monkey. Behav Neurosci 102:210–221
Google Scholar
- Tulving E, Schacter DL (1990) Priming and human memory systems Science 247:301–306
CAS PubMed Google Scholar
- Van Hoesen GW, Hyman BT (1990) Hippocampal formation anatomy and the patterns of pathology in Alzheimer's disease. Prog Brain Res 83:445–457
Google Scholar
- Van Hoesen GW, Pandya DN (1975) Some connections of the entorhinal (area 28) and perirhinal (area 35) cortices of the rhesus monkey. 1. Temporal lobe afferents. Brain Res 95:1–24
Google Scholar
- Weiskrantz L (1990) Problems of learning and memory one or multiple memory systems. Philos Trans R Soc Lond [Biol] 329:99–108
Google Scholar
- Wilson FAW, Rolls ET (1990) Neuronal responses related to the novelty and familiarity of visual stimuli in the substantia innominata, diagonal band of Broca and periventricular region of the primate basal forebrain. Exp Brain Res 80:104–120
Google Scholar
- Wilson FAW, Rolls ET (1993) The effects of stimulus novelty and familiarity on neuronal activity in the amygdala of monkeys performing recognition memory tasks. Exp Brain Res 93:367–382
Google Scholar
- Zola-Morgan S, Squire LR (1985a) Medial temporal lesions in monkeys impair memory on a variety of tasks sensitive to human amnesia. Behav Neurosci 99:22–34
Google Scholar
- Zola-Morgan S, Squire LR (1985b) Amnesia in monkeys after lesions of the mediodorsal nucleus of the thalamus. Ann Neurol 17:558–564
Google Scholar
- Zola-Morgan S, Squire LR, Amaral DG, Suzuki WA (1989) Lesions of perirhinal and parahippocampal cortex that spare the amygdala and hippocampal formation produce severe memory impairment. J Neurosci 9:4355–4370
Google Scholar