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Keywords: Differential conditioningClose
J Exp Biol (2021) 224 (9): jeb238535.
Published: 5 May 2021
.... Classical conditioning Proboscis extension response Maxilla labium extension response Absolute conditioning Differential conditioning Color conditioning chemotactile conditioning Multimodal learning Funding This project was funded by a Latin American Scholar fellowship...
J Exp Biol (2016) 219 (1): 12–16.
Published: 1 January 2016
...Toshiya Yamashita; S. Shuichi Haupt; Hidetoshi Ikeno; Hiroyuki Ai ABSTRACT The odor localization strategy induced by odors learned via differential conditioning of the proboscis extension response was investigated in honeybees. In response to reward-associated but not non-reward-associated odors...
Includes: Supplementary data
J Exp Biol (2011) 214 (19): 3300–3304.
Published: 1 October 2011
...–labium extension response). We differentially conditioned ants to discriminate between two long-chain hydrocarbons, one paired with sucrose and the other with quinine solution. Differential conditioning leads to the formation of a long-term memory retrievable at least 72 h after training. Long-term...
J Exp Biol (2010) 213 (1): 72–77.
Published: 1 January 2010
... [absolute conditioning (AC) and differential conditioning (DC)]. In the UV range, C. aenescens foragers failed to discriminate when presented with a small colour difference in both training procedures. Foragers also failed in the green range when trained with AC but showed significant bias towards...
J Exp Biol (2008) 211 (8): 1180–1186.
Published: 15 April 2008
... potentially creates a dilemma since environments rich in odometric cues might be poor in salient landmark cues, and vice versa . In the present study, honeybees were provided with differential conditioning to images of complex natural scenes, in order to determine if they could reliably learn to discriminate...
J Exp Biol (2005) 208 (4): 787–796.
Published: 15 February 2005
.... Differential conditioning experiments were carried out, in which moths had to distinguish between a rewarded (CS+)odorant and an explicitly unrewarded odorant (CS-), choosing odour concentrations giving the same learning rate in previous experiments. The best discrimination was found with β-myrcene...
J Exp Biol (2002) 205 (10): 1429–1437.
Published: 15 May 2002
...Yukihisa Matsumoto; Makoto Mizunami SUMMARY Temporal determinants of olfactory long-term memory retention in the cricket Gryllus bimaculatus were studied. Elementary appetitive and aversive conditioning procedures, as well as a differential conditioning procedure, were applied. In appetitive...