Staff Profile

Auditory neuroscience aims to understand how the brain processes information about sound. For many animals, hearing is important for keeping track of what's happening in their environment and for communication. For humans it underlies those most distinctively human attributes - speech and music. 

I study the brain pathways that underlie hearing; the chain of processing centres running from the ear to the cerebral cortex. I am to understand how these centres are organised and their role in processing sound using a diverse range of techniques, from recording and labelling single neurons to functional imaging and psychophysics in humans.

Other areas of interest include what underlies the generation of tinnitus (the perception of phantom sound) that blights the lives of its many suffers, and how hearing and vision interact.

Background

I graduated from Oxford University (Keble College) in Physiological Sciences and continued there first to gain my DPhil (supervised by Roy Kay), and then as Staines Medical Research Fellow at Exeter College. I left to spend two years as a Harkness Fellow at the University of Pittsburgh where I worked with Aage Møller. On my return to the UK, I joined Alan Palmer's lab at the MRC Institute of Hearing Research, Nottingham before being appointed to a lectureship in Physiological Sciences at Newcastle. I am currently in the Biosciences Institute where I am Professor of Auditory Neuroscience and director of the cross-faculty, Newcastle University Centre for Transformative Neuroscience. 

Esteem Factors

Joint winner of the 2010 George Davey Howells Memorial Prize for the Oxford Handbook of Auditory Science, a 3 volume survey of hearing science. Co-editor of Vol 2, The Auditory Brain.

Fellow of the Physiological Society

Societies

Association for Research in Otaryngology; British Neuroscience Association; Physiological Society; Society for Neuroscience

A main focus of my lab is the functional organisation of the auditory midbrain, the inferior colliculus.  This paired structure is the centre where information from lower brainstem centres converges. We have explored how sound frequency is mapped within it, and, by blocking receptors for neurotransmitters, how excitatory and inhibitory synapses determine the responses of its neurons. We have discovered that nitric oxide signalling is important for mediating synaptic transmission by NMDA receptors in the inferior colliculus, and reported evidence suggesting that this pathway may be activated in tinnitus.

Another emphasis of our research is on the connections the inferior colliculus receives from higher centres of the brain, including many that are not at first glance concerned with sound.  This suggests that the sound processing in the mibrain is influenced by prior information from other systems that helps with sound identification. For example, feedback from the movement centres may help to distinguish external sounds from those generated by our own movements.  

My research has also addressed how modulations in the amplitude and frequency of sounds are extracted and encoded. These temporal fluctuations are fundamental features of natural sounds, such as vocalisations. The information they contain plays an important part in our ability to identify sounds and to separate one sound from another when many competing sounds occur together.  Information about modulation is one of the main sounds attributes available to cochlear implant users. Our analysis of the responses of neurons in the midbrain to such sounds shows that neurons are selective for specific ranges of modulation rate, and we have shown using fMRI that modulation rate, as well as sound frequency, is mapped in the inferior colliculus.

Undergraduate Teaching

• PSC 3008  Physiology of the Nervous System (lecturer)

• PSC 2012 Integrated Physiology (lecturer)

• MBBS  Stage 2 (lecturer)

• MBBS   Accelerated Programme (lecturer)

• CMB 3000 Biomedical Sciences Project  (supervisor)

Postgraduate teaching 

• MMB8019    MRes  Sensory Systems (lecturer)

• Articles

  • Iskakova B, Forster LN, Mann KD, Brown M, Slack EL, Rees A, Pearce MS. Differences Between Self-Reported and Objectively Measured Hearing Loss at Age 61–63 Years: The Newcastle Thousand Families Birth Cohort. American Journal of Audiology 2023, 32(2), 500-506.
  • Olthof BM, Lyzwa D, Gartside SE, Rees A. Nitric oxide signalling underlies salicylate-induced increases in neuronal firing in the inferior colliculus: A central mechanism of tinnitus?. Hearing Research 2022, 424, 108585.
  • Gretenkord S, Olthof BMJ, Stylianou M, Rees A, Gartside SE, LeBeau FEN. Electrical stimulation of the ventral tegmental area (VTA) evokes sleep-like state transitions under urethane anaesthesia in the rat medial prefrontal cortex (mPFC) via dopamine D₁-like receptors. European Journal of Neuroscience 2020, 52(2), 2915-2930.
  • Othof BMJ, Gartside SE, Rees A. Puncta of Neuronal Nitric Oxide Synthase (nNOS) Mediate NMDA Receptor Signalling in the Auditory Midbrain. Journal of Neuroscience 2019, 39(5), 876-887.
  • Olthof BMJ, Rees A, Gartside SE. Multiple non-auditory cortical regions innervate the auditory midbrain. Journal of Neuroscience 2019, 39(45), 8916-8928.
  • Vuong QC, Laing M, Prabhu A, Tung HI, Rees A. Modulated stimuli demonstrate asymmetric interactions between hearing and vision. Scientific Reports 2019, 9, 7605.
  • Gretenkord S, Rees A, Whittington MA, Gartside SE, Lebeau FEN. Dorsal vs. ventral differences in fast Up-state-associated oscillations in the medial prefrontal cortex of the urethane-anesthetized rat. Journal of Neurophysiology 2017, 117(3), 1126-1142.
  • Poirier C, Baumann S, Dheerendra P, Joly O, Hunter D, Balezeau F, Sun L, Rees A, Petkov CI, Thiele A, Griffiths TD. Auditory motion-specific mechanisms in the primate brain. PLoS Biology 2017, 15(5), 1-24.
  • Orton L, Papasavvas C, Rees A. Commissural Gain Control Enhances the Midbrain Representation of Sound Location. Journal of Neuroscience 2016, 36(16), 4470-4481.
  • Baumann S, Joly O, Rees A, Petkov CI, Sun L, Thiele A, Griffiths TD. The Topography of Frequency and Time Representation in Primate Auditory Cortices. eLife 2015, 4, e03256.
  • Pearson F, Mann KD, Rees A, Davis A, Pearce MS. The Effect of Childhood Infection on Hearing Function at Age 61 to 63 Years in the Newcastle Thousand Families Study. Ear and Hearing 2015, 36(2), 185-190.
  • Laing M, Rees A, Vuong QC. Amplitude-modulated stimuli reveal auditory-visual interactions in brain activity and brain connectivity. Frontiers in Psychology 2015, 6, 1440.
  • Orton LD, Rees A. Intercollicular commissural connections refine the representation of sound frequency and level in the auditory midbrain. eLife 2014, 3, 1-17.
  • Palmer AR, Shackleton TM, Sumner CJ, Zobay O, Rees A. Classification of frequency response areas in the inferior colliculus reveals continua not discrete classes. Journal of Physiology 2013, 591(16), 4003-4025.
  • Pearson F, Mann KD, Nedellec R, Rees A, Pearce MS. Childhood infections, but not early life growth, influence hearing in the Newcastle thousand families birth cohort at age 14 years. BMC Ear, Nose and Throat Disorders 2013, 13, 9.
  • Orton LD, Poon PWF, Rees A. Deactivation of the inferior colliculus by cooling demonstrates intercollicular modulation of neuronal activity. Frontiers in Neural Circuits 2012, 6, 100.
  • Baumann S, Griffiths TD, Sun L, Petkov CI, Thiele A, Rees A. Orthogonal representation of sound dimensions in the primate midbrain. Nature Neuroscience 2011, 14(4), 423-425.
  • Nasimi A, Rees A. Regularly firing neurons in the inferior colliculus have a weak interaural intensity difference sensitivity. Journal of Comparative Physiology A: Neuroethology, Sensory, Neural, and Behavioral Physiology 2010, 196(12), 889-897.
  • Overath T, Kumar S, Stewart L, von Kriegstein K, Cusack R, Rees A, Griffiths TD. Cortical Mechanisms for the Segregation and Representation of Acoustic Textures. Journal of Neuroscience 2010, 30(6), 2070-2076.
  • Baumann S, Griffiths TD, Rees A, Hunter D, Sun L, Thiele A. Characterisation of the BOLD response time course at different levels of the auditory pathway in non-human primates. NeuroImage 2010, 50(3), 1099-1108.
  • Liu JD, Perez-Gonzalez D, Rees A, Erwin H, Wermter S. A biologically inspired spiking neural network model of the auditory midbrain for sound source localisation. Neurocomputing 2010, 74(1-3), 129-139.
  • Malmierca MS, Hernández O, Antunes FM, Rees A. Divergent and Point-to-Point Connections in the Commissural Pathway Between the Inferior Colliculi. Journal of Comparative Neurology 2009, 514(3), 226-239.
  • Coote EJ, Rees A. The distribution of nitric oxide synthase in the inferior colliculus of guinea pig. Neuroscience 2008, 154(1), 218-225.
  • Hernandez O, Rees A, Malmierca MS. A GABAergic component in the commissure of the inferior colliculus in rat. NeuroReport 2006, 17(15), 1611-1614.
  • Malmierca MS, Hernandez O, Rees A. Intercollicular commissural projections modulate neuronal responses in the inferior colliculus. European Journal of Neuroscience 2005, 21(10), 2701-2710.
  • Millman RE, Green GGR, Lorenzi C, Rees A. Effect of a noise modulation masker on the detection of second-order amplitude modulation. Hearing Research 2003, 178(1-2), 1-11.
  • Witton C, Simpson MIG, Henning GB, Rees A, Green GGR. Detection and direction-discrimination of diotic and dichotic ramp modulations in amplitude and phase. Journal of the Acoustical Society of America 2003, 113(1), 468-477.
  • Bal R, Green GGR, Rees A, Sanders DJ. Firing patterns of inferior colliculus neurons-histology and mechanism to change firing patterns in rat brain slices. Neuroscience Letters 2002, 317(1), 42-46.
  • Griffiths TD, Dean JL, Woods W, Rees A, Green GGR. The Newcastle Auditory Battery (NAB): A temporal and spatial test battery for use on adult naïve subjects. Hearing Research 2001, 154(1-2), 165-169.
  • Lorenzi C, Simpson MIG, Millman RE, Griffiths TD, Woods WP, Rees A, Green GGR. Second-order modulation detection thresholds for pure-tone and narrow-band noise carriers. Journal of the Acoustical Society of America 2001, 110(5), 2470-2478.
  • LeBeau FEN, Malmierca MS, Rees A. Iontophoretic studies in the inferior colliculus in vivo demonstrate a key role for GABA and glycine receptor mediated inhibition in shaping frequency response areas. Journal of Neuroscience 2001, 21(18), 7303-7312.
  • LeBeau FEN, Malmierca MS, Rees A. Iontophoresis in vivo demonstrates a key role for GABAA and glycinergic inhibition in shaping frequency response areas in the inferior colliculus of guinea pig. The Journal of Neuroscience 2001, 15, 7303-7312.
  • Chinnery PF, Elliott C, Green GR, Rees A, Coulthard A, Turnbull DM, Griffiths TD. The spectrum of hearing loss due to mitochondrial DNA defects. Brain 2000, 123(1), 82-92.
  • Witton C, Green GGR, Rees A, Henning GB. Monaural and binaural detection of sinusoidal phase modulation of a 500-Hz tone. Journal of the Acoustical Society of America 2000, 108(4), 1826-1833.
  • Griffiths TD, Green GGR, Rees A, Rees G. Human brain areas involved in the analysis of auditory movement. Human Brain Mapping 2000, 9(2), 72-80.
  • Griffiths TD, Green GGR, Rees A, Rees G. Human brain areas involved in the analysis of auditory movement. Human Brain Mapping 2000, 9(2), 72-80.
  • Talcott J, Witton C, McClean M, Hansen PC, Rees A, Green GGR, Stein JF. Dynamic sensory sensitivity and children's word decoding skills. Proceedings of the National Academy of Sciences of the United States 2000, 97(6), 2952-2957.
  • Talcott JB, Witton C, McLean MF, Hansen PC, Rees A, Green GGR, Stein JF. Dynamic sensory sensitivity and children's word decoding skills. Proceedings of the National Academy of Sciences of the United States of America 2000, 97(6), 2952-2957.
  • Griffiths TD, Rees A, Green GGR, Rees G. FMRI investigation of sound-movement analysis. NeuroImage 1999, 9(6), S791-.
  • Talcott JB, Witton C, McClean M, Hansen PC, Rees A, Green GGR, Stein JF. Can sensitivity to auditory frequency modulation predict children's phonological and reading skills?. NeuroReport 1999, 10(10), 2045-2050.
  • Rees A., Sarbaz A., Malmierca M.S. and Le Beau F. Regularity of spike discharge in the inferior colliculus. Journal of Neurophysiology 1997, 77, 2945-2965.
  • Malmierca M.S., Le Beau F. and Rees A. The topographical organisation of descending projections from the central nucleus of the inferior colliculus. Hearing Research 1996, 93, 167-180.
  • Le Beau F., Rees A. and Malmierca M.S. The contribution of GABA- and glycine mediated inhibition to the monaural temporal response properties of neurons in the inferior colliculus. Journal of Neurophysiology 1996, 75, 902-919.
  • Rees A. Sensory maps: aligning maps of auditory and visual space. Current Biology 1996, 6, 955-958.

• Book Chapters

  • Rees A. The Inferior Colliculus. In: Grothe B, ed. The Senses: A Comprehensive Reference Volume 2: Audition. Amsterdam: Elsevier, Academic Press, 2021, pp.566-600.
  • Rees A, Orton LD. Unifying the Midbrain: The Commissure of the Inferior Colliculus. In: Kandler, K, ed. The Oxford Handbook of the Auditory Brainstem. Oxford University Press, 2018.
  • Rees A, Langner G. Temporal Coding in the Auditory Midbrain. In: Winer, J.A., Schreiner, C, ed. The Inferior Colliculus. New York: Springer, 2005, pp.346-376.
  • Thornton SK, Rees A. The dorsal nucleus of the lateral lemniscus shapes auditory responses in the inferior colliculus. In: Breebart, DJ; Houstma, AJM; Kohlrausch, A; Prijs, VF; Schoonhoven, R, ed. Physiological and psychophysical bases of auditory function: proceedings of the 12th International Symposium on Hearing. Maastricht: Shaker Verlag, 2001, pp.298-305.

• Conference Proceedings (inc. Abstracts)

  • Vuong QC, Parikh JD, Laing M, Blamire AM, Rees A. Visual modulation of auditory discrimination correlates with GABA in parietal multisensory area. In: Organisation of Human Brain Mapping OHBM 2016 Annual General Meeting. 2016, Geneva: Organization for Human Brain Mapping.
  • Malmierca MS, Hernandez O, Falconi A, Lopez-Poveda EA, Merchan M, Rees A. The commissure of the inferior colliculus shapes frequency response areas in rat: An in vivo study using reversible blockade with microinjection of kynurenic acid. In: Experimental Brain Research: Scientific Meeting on Central Auditory Processing - Integration with Other Systems. 2003, Ascona, Switzerland: Springer.

• Edited Book

  • Rees A, Palmer AR, ed. The Auditory Brain. Oxford, UK: Oxford University Press, 2010.

• Reviews

  • Rees A, Malmierca MS. Processing of Dynamic Spectral Properties of Sounds. International Review of Neurobiology 2005, 70, 299-330.
  • Rees A, Malmierca MS. Processing of dynamic spectral properties of sounds. International Review of Neurobiology: Auditory Spectral Processing 2005, 70, 299-330.
  • Joris PX, Schreiner CE, Rees A. Neural processing of amplitude-modulated sounds. Physiological Reviews 2004, 84(2), 541-577.
  • Griffiths TD, Rees A, Green GGR. Disorders of human complex sound processing. Neurocase 1999, 5(5), 365-378.