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Katrin Krumbholz

Scientific Programme Leader, Faculty of Medicine & Health Sciences

Contact

workRoom 205 40 - Hearing Sciences
University Park
Nottingham
NG7 2RD
UK
work0115 74-86941
Katrin.Krumbholz@nottingham.ac.uk
https://www.nottingham.ac.uk/research/groups/hearingsciences/index.aspx

Biography

Previous appointments:

20018-current: Research Programme Leader, School of Medicine, University of Nottingham, UK
2009-2018: Programme Leader, Medical Research Council Institute of Hearing Research, UK
2004-2009: Programme Leader Track, Medical Research Council Institute of Hearing Research, UK
2002-2004: Senior Research Associate, Research Centre Jülich, Institute of Neuroscience and Medicine, DE
2001-2002: Research Associate, University Hospital Münster, Institute of Experimental Audiology, DE
1998-2001: Research Associate, University of Cambridge, Department of Physiology Development and Neuroscience, UK

Expertise Summary

I am an expert in hearing research and non-invasive neuro-recording techniques, particularly electroencephalography (EEG) and magnetic resonance imaging (MRI). I have extensive experience in recording and analyzing cortical auditory-evoked potentials (CAEPs), auditory brainstem responses (ABRs), and auditory-evoked functional MRI data.

Research Summary

Recent Publications

DE BOER, JESSICA and KRUMBHOLZ, KATRIN, 2018. Auditory Attention Causes Gain Enhancement and Frequency Sharpening at Successive Stages of Cortical Processing-Evidence from Human Electroencephalography JOURNAL OF COGNITIVE NEUROSCIENCE. 30(6), 785-798
FLETCHER, M. D., KRUMBHOLZ, K. and DE BOER, J., 2016. Effect of Contralateral Medial Olivocochlear Feedback on Perceptual Estimates of Cochlear Gain and Compression: J Assoc Res Otolaryngol J Assoc Res Otolaryngol. 17(6), 559-575
DUQUE, D., WANG, X., NIETO-DIEGO, J., KRUMBHOLZ, K. and MALMIERCA, M. S., 2016. Neurons in the inferior colliculus of the rat show stimulus-specific adaptation for frequency, but not for intensity: Sci Rep Sci Rep. 6, 24114
SCHONWIESNER, M., DECHENT, P., VOIT, D., PETKOV, C. I. and KRUMBHOLZ, K., 2015. Parcellation of Human and Monkey Core Auditory Cortex with fMRI Pattern Classification and Objective Detection of Tonotopic Gradient Reversals: Cereb Cortex Cereb Cortex. 25(10), 3278-89

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Current Research

Over the past ~14 years, our research has been focussed on using non-invasive neuro-recording techniques to unravel central auditory processing mechanisms in humans. We use EEG and fMRI to investigate how basic auditory features, such as frequency, pitch and location, are represented in subcortical and cortical auditory structures, and how these representations change in hearing loss. A particular interest in on modulatory mechanisms, including lateral inhibition, efferent control and adaptation. In our past research, we have used adaptation as a tool for probing auditory neuronal tuning properties.

Past Research

- We have used high-resolution fMRI and micro-structural MRI at 3 and 7T to reveal the organization of early auditory cortex in normal-hearing humans (Besle et al., 2019; Schonwiesner et al., 2015; Langers et al., 2014a, b)

- We have used EEG adaptation to demonstrate that auditory selective attention involves neuronal gain and neuronal sharpening (de Boer & Krumbholz, 2018)

- We have used EEG to demonstrate that the auditory brainstem response to speech (speech ABR) is strongly affected by its cochlear place of origin (Nutall et al., 2015)

- We have used psychoacoustics to measure the effect of the olivo-cochlear efferent system on active cochlear gain (Fletcher et al., 2013, 2015, 2016)

- We have used EEG to investigate the mechanisms of auditory adaptation (Briley & Krumbholz, 2013; Lanting et al. 2013)

- We have used cortical auditory-evoked potentials and fields to reveal cortical representation mechanisms of musical pitch (Briley et al., 2013; Lutkenhoner et al., 2011; Seither-Preisler et al., 2006a, b), sound location and motion (Edmonds & Krumbholz, 2014; Magezi & Krumbholz, 2010; Krumbholz et al., 2007), and phonemic information (Edmonds et al., 2010; Hewson-Stoate et al., 2006)

Future Research

Our current research aims to apply non-invasive methods to investigate changes in central auditory processing that may arise in consequence of peripheral hearing damage, such as sensorineural hearing loss and auditory deafferentation. Central auditory processing changes may underlie some of the most debilitating impairments associated with such damage - tinnitus, hyperacusis and speech-in-noise difficulty, which are still poorly understood, and not efficiently addressed by current treatments. Our current research projects aim to develop methodology for measuring hearing loss-related neuronal hyper-excitability and cortical tonotopic reorganization, both of which have been suggested as possible causes of tinnitus.

DE BOER, JESSICA and KRUMBHOLZ, KATRIN, 2018. Auditory Attention Causes Gain Enhancement and Frequency Sharpening at Successive Stages of Cortical Processing-Evidence from Human Electroencephalography JOURNAL OF COGNITIVE NEUROSCIENCE. 30(6), 785-798
FLETCHER, M. D., KRUMBHOLZ, K. and DE BOER, J., 2016. Effect of Contralateral Medial Olivocochlear Feedback on Perceptual Estimates of Cochlear Gain and Compression: J Assoc Res Otolaryngol J Assoc Res Otolaryngol. 17(6), 559-575
DUQUE, D., WANG, X., NIETO-DIEGO, J., KRUMBHOLZ, K. and MALMIERCA, M. S., 2016. Neurons in the inferior colliculus of the rat show stimulus-specific adaptation for frequency, but not for intensity: Sci Rep Sci Rep. 6, 24114
SCHONWIESNER, M., DECHENT, P., VOIT, D., PETKOV, C. I. and KRUMBHOLZ, K., 2015. Parcellation of Human and Monkey Core Auditory Cortex with fMRI Pattern Classification and Objective Detection of Tonotopic Gradient Reversals: Cereb Cortex Cereb Cortex. 25(10), 3278-89
NUTTALL, H. E., MOORE, D. R., BARRY, J. G., KRUMBHOLZ, K. and DE BOER, J., 2015. The influence of cochlear spectral processing on the timing and amplitude of the speech-evoked auditory brain stem response: J Neurophysiol J Neurophysiol. 113(10), 3683-91
GILBERT, H. J., SHACKLETON, T. M., KRUMBHOLZ, K. and PALMER, A. R., 2015. The neural substrate for binaural masking level differences in the auditory cortex: J Neurosci J Neurosci. 35(1), 209-20
FLETCHER, M., DE BOER, J. and KRUMBHOLZ, K., 2015. Is off-frequency overshoot caused by adaptation of suppression?: J Assoc Res Otolaryngol J Assoc Res Otolaryngol. 16(2), 241-53
EDMONDS, B. A. and KRUMBHOLZ, K., 2014. Are interaural time and level differences represented by independent or integrated codes in the human auditory cortex?: J Assoc Res Otolaryngol J Assoc Res Otolaryngol. 15(1), 103-14
LANGERS, D. R., KRUMBHOLZ, K., BOWTELL, R. W. and HALL, D. A., 2014. Neuroimaging paradigms for tonotopic mapping (I): the influence of sound stimulus type: Neuroimage Neuroimage. 100, 650-62
LANGERS, D. R., SANCHEZ-PANCHUELO, R. M., FRANCIS, S. T., KRUMBHOLZ, K. and HALL, D. A., 2014. Neuroimaging paradigms for tonotopic mapping (II): the influence of acquisition protocol: Neuroimage Neuroimage. 100, 663-75
LANTING, C. P., BRILEY, P. M., SUMNER, C. J. and KRUMBHOLZ, K., 2013. Mechanisms of adaptation in human auditory cortex: J Neurophysiol J Neurophysiol. 110(4), 973-83
FLETCHER, M., DE BOER, J. and KRUMBHOLZ, K., 2013. Is overshoot caused by an efferent reduction in cochlear gain?: Adv Exp Med Biol Adv Exp Med Biol. 787, 65-72
MONAGHAN, J. J., KRUMBHOLZ, K. and SEEBER, B. U., 2013. Factors affecting the use of envelope interaural time differences in reverberation: J Acoust Soc Am J Acoust Soc Am. 133(4), 2288-300
BRILEY, P. M. and KRUMBHOLZ, K., 2013. The specificity of stimulus-specific adaptation in human auditory cortex increases with repeated exposure to the adapting stimulus: J Neurophysiol J Neurophysiol. 110(12), 2679-88
BRILEY, P. M., BREAKEY, C. and KRUMBHOLZ, K., 2013. Evidence for pitch chroma mapping in human auditory cortex: Cereb Cortex Cereb Cortex. 23(11), 2601-10
SUMNER, C. J. and KRUMBHOLZ, K., 2012. Which bit of auditory cortex does 'where'?: J Physiol J Physiol. 590(16), 3645
DE BOER, J., THORNTON, A. R. and KRUMBHOLZ, K., 2012. What is the role of the medial olivocochlear system in speech-in-noise processing?: J Neurophysiol J Neurophysiol. 107(5), 1301-12
BARRETT, D. J. and KRUMBHOLZ, K., 2012. Evidence for multisensory integration in the elicitation of prior entry by bimodal cues: Exp Brain Res Exp Brain Res. 222(1-2), 11-20
LUTKENHONER, B., SEITHER-PREISLER, A., KRUMBHOLZ, K. and PATTERSON, R. D., 2011. Auditory cortex tracks the temporal regularity of sustained noisy sounds: Hear Res Hear Res. 272(1-2), 85-94
EDMONDS, B. A., JAMES, R. E., UTEV, A., VESTERGAARD, M. D., PATTERSON, R. D. and KRUMBHOLZ, K., 2010. Evidence for early specialized processing of speech formant information in anterior and posterior human auditory cortex: Eur J Neurosci Eur J Neurosci. 32(4), 684-92
MAGEZI, D. A. and KRUMBHOLZ, K., 2010. Evidence for opponent-channel coding of interaural time differences in human auditory cortex: J Neurophysiol J Neurophysiol. 104(4), 1997-2007
KRUMBHOLZ, K., MAGEZI, D. A., MOORE, R. C. and PATTERSON, R. D., 2009. Binaural sluggishness precludes temporal pitch processing based on envelope cues in conditions of binaural unmasking: J Acoust Soc Am J Acoust Soc Am. 125(2), 1067-74
BALAGUER-BALLESTER, E., CLARK, N. R., COATH, M., KRUMBHOLZ, K. and DENHAM, S. L., 2009. Understanding pitch perception as a hierarchical process with top-down modulation: PLoS Comput Biol PLoS Comput Biol. 5(3), e1000301
KRUMBHOLZ, K., NOBIS, E. A., WEATHERITT, R. J. and FINK, G. R., 2009. Executive control of spatial attention shifts in the auditory compared to the visual modality: Hum Brain Mapp Hum Brain Mapp. 30(5), 1457-69
MAGEZI, D. A. and KRUMBHOLZ, K., 2008. Can the binaural system extract fine-structure interaural time differences from noncorresponding frequency channels?: J Acoust Soc Am J Acoust Soc Am. 124(5), 3095-3107
SCHONWIESNER, M., KRUMBHOLZ, K., RUBSAMEN, R., FINK, G. R. and VON CRAMON, D. Y., 2007. Hemispheric asymmetry for auditory processing in the human auditory brain stem, thalamus, and cortex: Cereb Cortex Cereb Cortex. 17(2), 492-9
KRUMBHOLZ, K., HEWSON-STOATE, N. and SCHONWIESNER, M., 2007. Cortical response to auditory motion suggests an asymmetry in the reliance on inter-hemispheric connections between the left and right auditory cortices: J Neurophysiol J Neurophysiol. 97(2), 1649-55
KRUMBHOLZ, K., EICKHOFF, S. B. and FINK, G. R., 2007. Feature- and object-based attentional modulation in the human auditory "where" pathway: J Cogn Neurosci J Cogn Neurosci. 19(10), 1721-33
SEITHER-PREISLER, A., JOHNSON, L., KRUMBHOLZ, K., NOBBE, A., PATTERSON, R., SEITHER, S. and LUTKENHONER, B., 2007. Tone sequences with conflicting fundamental pitch and timbre changes are heard differently by musicians and nonmusicians: J Exp Psychol Hum Percept Perform J Exp Psychol Hum Percept Perform. 33(3), 743-51
SEITHER-PREISLER, A., PATTERSON, R. D., KRUMBHOLZ, K., SEITHER, S. and LUTKENHONER, B., 2006. From noise to pitch: transient and sustained responses of the auditory evoked field: Hear Res Hear Res. 218(1-2), 50-63
SEITHER-PREISLER, A., PATTERSON, R., KRUMBHOLZ, K., SEITHER, S. and LUTKENHONER, B., 2006. Evidence of pitch processing in the N100m component of the auditory evoked field: Hear Res Hear Res. 213(1-2), 88-98
HEWSON-STOATE, N., SCHONWIESNER, M. and KRUMBHOLZ, K., 2006. Vowel processing evokes a large sustained response anterior to primary auditory cortex: Eur J Neurosci Eur J Neurosci. 24(9), 2661-71
KRUMBHOLZ, K., SCHONWIESNER, M., VON CRAMON, D. Y., RUBSAMEN, R., SHAH, N. J., ZILLES, K. and FINK, G. R., 2005. Representation of interaural temporal information from left and right auditory space in the human planum temporale and inferior parietal lobe: Cereb Cortex Cereb Cortex. 15(3), 317-24
KRUMBHOLZ, K., SCHONWIESNER, M., RUBSAMEN, R., ZILLES, K., FINK, G. R. and VON CRAMON, D. Y., 2005. Hierarchical processing of sound location and motion in the human brainstem and planum temporale: Eur J Neurosci Eur J Neurosci. 21(1), 230-8
KRUMBHOLZ, K., BLEECK, S., PATTERSON, R. D., SENOKOZLIEVA, M., SEITHER-PREISLER, A. and LUTKENHONER, B., 2005. The effect of cross-channel synchrony on the perception of temporal regularity: J Acoust Soc Am J Acoust Soc Am. 118(2), 946-54
SEITHER-PREISLER, A., KRUMBHOLZ, K., PATTERSON, R., SEITHER, S. and LUTKENHONER, B., 2004. Interaction between the neuromagnetic responses to sound energy onset and pitch onset suggests common generators: Eur J Neurosci Eur J Neurosci. 19(11), 3073-80
KRUMBHOLZ, K., MARESH, K., TOMLINSON, J., PATTERSON, R. D., SEITHER-PREISLER, A. and LUTKENHONER, B., 2004. Mechanisms determining the salience of coloration in echoed sound: influence of interaural time and level differences: J Acoust Soc Am J Acoust Soc Am. 115(4), 1696-704
LUTKENHONER, B., KRUMBHOLZ, K. and SEITHER-PREISLER, A., 2003. Studies of tonotopy based on wave N100 of the auditory evoked field are problematic: Neuroimage Neuroimage. 19(3), 935-49
SEITHER-PREISLER, A., KRUMBHOLZ, K. and LUTKENHONER, B., 2003. Sensitivity of the neuromagnetic N100m deflection to spectral bandwidth: a function of the auditory periphery?: Audiol Neurootol Audiol Neurootol. 8(6), 322-37
LUTKENHONER, B., KRUMBHOLZ, K., LAMMERTMANN, C., SEITHER-PREISLER, A., STEINSTRATER, O. and PATTERSON, R. D., 2003. Localization of primary auditory cortex in humans by magnetoencephalography: Neuroimage Neuroimage. 18(1), 58-66
KRUMBHOLZ, K., PATTERSON, R. D., SEITHER-PREISLER, A., LAMMERTMANN, C. and LUTKENHONER, B., 2003. Neuromagnetic evidence for a pitch processing center in Heschl's gyrus: Cereb Cortex Cereb Cortex. 13(7), 765-72
KRUMBHOLZ, K., PATTERSON, R. D., NOBBE, A. and FASTL, H., 2003. Microsecond temporal resolution in monaural hearing without spectral cues?: J Acoust Soc Am J Acoust Soc Am. 113(5), 2790-800
KRUMBHOLZ, K. and NOBBE, A., 2002. Buildup and breakdown of echo suppression for stimuli presented over headphones-the effects of interaural time and level differences: J Acoust Soc Am J Acoust Soc Am. 112(2), 654-63
PRESSNITZER, D., PATTERSON, R. D. and KRUMBHOLZ, K., 2001. The lower limit of melodic pitch: J Acoust Soc Am J Acoust Soc Am. 109(5 Pt 1), 2074-84
KRUMBHOLZ, K. and SCHMIDT, S., 2001. Evidence for an analytic perception of multiharmonic sounds in the bat, Megaderma lyra, and its possible role for echo spectral analysis: J Acoust Soc Am J Acoust Soc Am. 109(4), 1705-16
KRUMBHOLZ, K., PATTERSON, R. D. and NOBBE, A., 2001. Asymmetry of masking between noise and iterated rippled noise: evidence for time-interval processing in the auditory system: J Acoust Soc Am J Acoust Soc Am. 110(4), 2096-107
KRUMBHOLZ, K., PATTERSON, R. D. and PRESSNITZER, D., 2000. The lower limit of pitch as determined by rate discrimination: J Acoust Soc Am J Acoust Soc Am. 108(3 Pt 1), 1170-80
WIEGREBE, L. and KRUMBHOLZ, K., 1999. Temporal resolution and temporal masking properties of transient stimuli: data and an auditory model: J Acoust Soc Am J Acoust Soc Am. 105(5), 2746-56
KRUMBHOLZ, K. and SCHMIDT, S., 1999. Perception of complex tones and its analogy to echo spectral analysis in the bat, Megaderma lyra: J Acoust Soc Am J Acoust Soc Am. 105(2 Pt 1), 898-911
KRUMBHOLZ, K. and WIEGREBE, L., 1998. Detection thresholds for brief sounds--are they a measure of auditory intensity integration?: Hear Res Hear Res. 124(1-2), 155-69