Pests are the target of pesticides. However, pesticides affect pollinators simultaneously, such as honey bees. Imidacloprid, a common systemic pesticide, acts on the nicotinic acetylcholine receptors and causes hyperexcitation in the nervous system of insects. Previous study showed the decrease of honey bees’ learning ability after exposing to sublethal dosage of imidacloprid in the larval stage. The learning ability may be related to mushroom bodies, which is responsible for the multisensory integration and are associated with learning, memory and cognitive processing in the insect brain. In the mushroom bodies of honey bee worker, the synaptic connectivity increases with age, and so as the learning ability. This synaptic plasticity is the base for the honey bees to cope with different tasks in the environment and make internal adjustment. In this study, immunohistochemistry is used to label the synaptic units in the calyces of mushroom bodies to see the sublethal effects of imidacloprid on the neural development. The results indicate that the density of synaptic units in the calyces region decreases after feeding with sublethal dosages of imidacloprid. This links the decrease of olfactory learning ability to abnormal neural connectivity, and thus demonstrates the imidacloprid impairs the development of nervous system from the larval stage of honey bees.