FRANKFURT – The intricate relationship between mammals and their sense of smell has often been overshadowed by the dominance of other senses, especially in studies concerning sensory perception. An intriguing breakthrough has recently emerged from the research of Tobias Ackels, a rising star in the field of olfactory neuroscience. Awarded the prestigious Paul Ehrlich and Ludwig Darmstaedter Early Career Award for 2025, Ackels’ research delves deeper into understanding how animals decode complex olfactory information and how this fundamental sense operates even in conditions we previously considered to be insurmountable barriers to sensory processing.
Traditionally, a “sniff” was regarded as the most basic unit of olfactory information, a notion that has come under scrutiny with Ackels’ innovative research. His pioneering work introduces a groundbreaking odor application device capable of releasing individual molecules and their mixtures in precise millisecond pulses. This technological advancement provides a new lens through which we can observe olfactory processing in real-time. The findings from Ackels’ experiments challenge the long-standing belief regarding sniffing and point toward a more complex and nuanced understanding of how mammals interpret odors.
The human nose can distinguish thousands of different smells, and studies indicate that this olfactory system lays the groundwork for vital survival functions, including foraging for food, finding mates, and evading predators. Ackels’ research demonstrates that mammals, much like humans, possess olfactory cells in their nasal mucosa that are hyper-sensitive to various odorants. Moreover, each type of olfactory receptor corresponds to a unique olfactory cell that transmits specific signals to the brain when an odorant binds to it. For instance, while mice have approximately 1,000 olfactory receptor types, humans only have around 350. These cellular dynamics underline the sophisticated biology of olfaction, which is essential in shaping behavior across the animal kingdom.
Ackels’ experimental design involves the synchronous presentation of odor mixtures to groups of mice. He meticulously crafted situations simulating natural conditions where mice had to discern between odors emanating from the same source versus those coming from different locations. The results were astonishing: mice were able to learn and respond to both synchronous and asynchronous odor cues, mastering the distinction at impressive frequencies up to 40 Hertz. This suggests that mammals are finely tuned to detect and interpret multiple odor sources at lightning speed, equipping them with a crucial advantage in their environments.
The implications of this research extend far beyond mere interest in animal behavior. The varying time-lag associated with the arrival of odors at olfactory receptors enhances the amount of information processed by the brain. This phenomenon is facilitated by neural circuits in the olfactory bulb, where the signals from different receptor types converge and amplify the informational richness of the olfactory experience. Ackels reveals that this heightened processing allows mammals to store olfactory information fleetingly, making it easier to adapt and respond to rapidly changing environmental stimuli.
His findings indicate that the convergence of signals within the olfactory bulb is equally vital for processing emotional and memory-related components. The direct transmission of olfactory information to the limbic system emphasizes how closely linked our sense of smell is to emotional responses and memory recall. This connection suggests that prior experiences significantly influence how new scents are perceived and interpreted, hinting at an evolutionary advantage provided by olfaction.
One of the most striking aspects of Ackels’ research focuses on the role of interneurons, which play a pivotal role in neuroplasticity within the olfactory bulb. These granule cells, known to renew themselves throughout an individual’s life, challenge the previously accepted dogma that adult neurons do not undergo division. The implications of this discovery could reshape our understanding of the neural circuitry involved in olfactory processing and emotional responses.
In light of his breakthrough findings, Ackels has engaged in collaborations with clinicians at the Deutsches Zentrum für neurodegenerative Erkrankungen (DZNE) in Bonn. The potential relationship between olfactory deficits and early-onset dementia presents an exciting research avenue that Ackels is keen to explore further. The hypothesis that changes in olfactory perception may act as precursors to neurodegenerative diseases could lead to proactive measures in diagnosis and intervention, fundamentally changing how we approach early detection of cognitive disorders.
Ackels’ journey is equally remarkable as his discoveries. Initially studying biology at RWTH Aachen University, he robustly embarked on his research career, eventually earning his doctorate in 2015. His subsequent tenure as a postdoctoral researcher at the esteemed Francis Crick Institute in London further solidified his standing in the scientific community. Now, as a W2 professor at the University of Bonn, he leads a dedicated team focused on the sensory dynamics and behavioral responses related to olfactory processing.
With the imminent award ceremony scheduled for March 14, 2025, in Frankfurt, Ackels’ findings promise to shape not only the academic landscape but also practical methodologies for clinical evaluation and treatment. Moreover, the dialogue surrounding behavior, cognition, and sensory perception continues to evolve, fostering interdisciplinary discussions that transcend traditional boundaries in neuroscience and behavioral research.
As we look toward the future, Ackels’ groundbreaking research is carving a path that illuminates the complex interplay between olfactory perception and behavior, fostering deeper understanding and appreciation of the unseen forces that shape our emotional and cognitive lives.
—
Subject of Research: Olfactory processing and perception in mammals
Article Title: Decoding Smells: New Insights into Olfactory Perception
News Publication Date: 2023-10-10
Web References: www.paul-ehrlich-stiftung.de
References: N/A
Image Credits: Rolf Mueller, University of Bonn
Keywords: Olfactory perception, odor processing, behavioral neuroscience, memory, neuroplasticity, animal behavior, cognitive disorders.
Tags: 2025 Paul Ehrlich Awardadvancements in neuroscience researchcomplex odor decodinginnovative sniffing techniquesmammals sense of smellodor application technologyolfactory processing breakthroughsreal-time olfactory experimentssensory perception researchsignificance of smell in survivalTobias Ackels olfactory neuroscienceunderstanding sensory barriers
