Pagliaro AH, Arya P, Sharbaf Y, and Gobes SMH (2020). Hemispheric asymmetry of calbindin-positive neurons is associated with successful song imitation. Brain Research. 1732: 146679

Pagliaro AH, Arya P, Piristine HC, Lord JS, and Gobes SMH (2020). Bilateral brain activity in auditory regions is necessary for successful vocal learning in songbirds. Neuroscience Letters. 718:134730

Gobes SMH, Jennings RB, and Maeda RK (2019). The sensitive period for auditory-vocal learning in the zebra finch: consequences of limited-model availability and multiple-tutor paradigms on song imitation. Behavioural Processes. 163: 5-12

Huang Z, Khaled HG, Kirschmann M, Gobes SMH, Hahnloser RHR (2018). Excitatory and inhibitory synapse turnover associated with song learning in zebra finches” eLife 2018;7:e37571 DOI: 10.7554/eLife.37571

Olson EM, Maeda RK, and Gobes SMH (2016) Mirrored patterns of lateralized neuronal activation reflect old and new memories in the avian auditory cortex. Neuroscience, 330, 395-402, doi:10.1016/j.neuroscience.2016.06.009

Piristine HC, Choetzo T, and Gobes SMH (2016) A sensorimotor area in the songbird brain is required for production of vocalizations in the song learning period of development. Developmental Neurobiology, 76, 1213-1225, DOI: 10.1002/dneu.22384

Otchy TM, Wolff SBE*, Rhee J*, Pehlevan C*, Kawai R, Kempf A, Gobes SMH, and Ölveczky BP (2015) Acute off-target effects of neural circuit manipulations. Nature, 528, 358-363

Chirathivat N, Raja SC, and Gobes SMH (2015) Hemispheric dominance underlying the neural substrate for learned vocalizations develops with experience. Scientific Reports, 5 (1359): DOI: 10.1038/srep11359

Gobes SMH*, Moorman S*, van de Kamp FC, Zandbergen MA, and Bolhuis JJ (2015) Learning-related brain hemispheric dominance in sleeping songbirds. Scientific Reports, 5 (9041): DOI:10.1038/srep09041

Gobes SMH, Fritz JB, Bolhuis JJ. (2013) Chapter 15, Brain mechanisms of auditory learning and memory in songbirds and mammals; p.295-315. In: Birdsong, Speech, and Language: Exploring the Evolution of Mind and Brain. Bolhuis JJ, Everaert M, editors. Cambridge, Massachusetts: The MIT Press; 2013.

Roberts TF, Gobes SMH, Murugan M, Ölveczky BP, and Mooney R (2012) Motor circuits are required to encode a sensory model for imitative learning. Nature Neuroscience, 15, 1454-1459

Bolhuis, JJ, Gobes SMH, Terpstra NJ, den Boer-Visser AM, and Zandbergen MA (2012) Learning-Related Neuronal Activation in the Zebra Finch Song System Nucleus HVC in Response to the Bird's Own Song. PloS ONE, 7(7): e41556. doi:10.1371/journal.pone.0041556

Moorman SM, Gobes SMH, Kuijpers M, Kerkhofs A, Zandbergen MA, and Bolhuis JJ (2012) Human-like brain hemispheric dominance in birdsong learning" Proceedings of the National Academy of Sciences of the USA,109, 12782-87

Gobes SMH, Zandbergen MA, and Bolhuis JJ (2010) Memory in the making: Localized brain activation related to song learning in young songbirds. Proceedings of the Royal Society B, 277, 3343-51

Gobes SMH, ter Haar SM, Vignal C, Vergne AL, Mathevon N, and Bolhuis, JJ (2009) Differential responsiveness in brain and behavior to sexually dimorphic long calls in male and female zebra finches. Journal of Comparative Neurology, 516, 312-320

Richardson MK, Gobes SMH, van Leeuwen A, Poelman A, Pieau C, and Sánchez-Villagra MR (2009) Tetrapod Limb Development: a Case Study in Heterochrony. Journal of Experimental Zoology Part B-Molecular and Developmental Evolution. 312B, 639-664

Gobes SMH and Bolhuis JJ (2008) Bird brains key to the function of sleep. Science, 322, 1789-1789 (letter to the editor)

Boumans T, Gobes SMH, Poirier C, Theunissen FE, Vandersmissen L, Pintjens W, Verhoye M, Bolhuis JJ, and Van der Linden A (2008) Functional MRI of Auditory Responses in the Zebra Finch Forebrain Reveals a Hierarchical Organisation Based on Response Strength but not Selectivity. PLoS ONE, 3(9), e3184

Gobes SMH and Bolhuis JJ (2007) Birdsong Memory: A Neural Dissociation between Song Recognition and Production, Current Biology, 17, 789-793

Knoch ME, Gobes SMH, Pavlovska I, Su C, Mistlberger RE, and Glass JD (2004) Short-term exposure to constant light promotes strong circadian phase-resetting responses to nonphotic stimuli in Syrian hamsters. European Journal of Neuroscience, 19, 2779-2790