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1. Beyond intersubjectivity in olfactory psychophysics II: Troubles with the Object

   https://doi.org/10.1177/0306312720915646  

   Alač, Morana (June 2020, Social Studies of Science)

   null (Ed.)

   This article takes advantage of the sense of smell’s peculiar spatiality to reflect on how we may render our engagement with the world other than through manipulating well-defined objects. The lived spatiality associated with olfaction is not reducible to the known parameters of ‘distant observation’ and ‘reaching toward’, familiar from the visual and tactile modalities. Instead, olfactory spatiality is one of immersion: Odors ask us to give up our dominance while we continue to be involved. The article attends to this immersive quality of the sense of smell by tracing multimodal, embodied qualities of mundane events in a laboratory of olfactory psychophysics, also considering the spatial organization of laboratory chambers, and how researchers fashion their bodies while they recognize the frailty of their enterprise. To engage these complexities, the article illustrates an exercise in experimenting with re-production, re-enactment and re-experiencing. While the exercise functions as a reflection on how to orient a laboratory study to non-ocular dimensions of science, the article, in parallel, enquires into semiotic articulations of smell experiences. By pointing out how smell language, rather than being ‘mute’, speaks the spatial quality of our olfactory experiences, it concludes the argument against the olfactory ineffability, initiated in the sister essay on ‘troubles with the Subject’. 

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2. Birds and Their Extraordinary Sense of Smell

   https://doi.org/10.3389/frym.2024.1332305  

   Li, Renee; Mantha, Nivritti; Ojiro, Ichie; Matsunami, Hiroaki; Driver, Robert (September 2024, Frontiers for Young Minds)

   Smell is one of the five senses we use to experience the world. It allows humans and other animals to find their food, avoid danger, and even recognize family members. Animals detect smells with olfactory receptors, special proteins that sit on the surface of the nose cells. These interact with odor molecules (small particles that have a smell) and send signals to the brain so the animal can perceive the smell. We know mammals have hundreds of olfactory receptors and can detect tens of thousands of smells, but what about birds? For decades, many people thought that birds did not use smell in their daily lives, but recent studies have shown that birds respond to smell. We show that many birds have a large number of olfactory receptors similar to mammals, strengthening the case for smell playing an important role in the life of birds. 

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3. Getting Nosy: Olfactory Rosette Morphology and Lamellar Microstructure of Two Chondrichthyan Species

   https://doi.org/10.1093/icb/icae103  

   Simonitis, Lauren_Eve; Clark, Aubrey_E; Barskaya, Elizaveta; Castillo, Gabriella; Porter, Marianne; Meredith, Tricia (July 2024, Integrative And Comparative Biology)

   Synopsis To smell, fish rely on passive water flow into their olfactory chambers and through their olfactory rosettes to detect chemical signals in their aquatic environment. The olfactory rosette is made up of secondarily folded tissues called olfactory lamellae. The olfactory morphology of cartilaginous fishes varies widely in both rosette gross morphology and lamellar microstructure. Previous research has shown differences in lamellar sensory morphology depending on the position along the rosette in hammerheads (family Sphyrnidae). Here, we investigate if this pattern continues in members of two other chondrichthyan families: Squalidae and Chimaeridae. Using contrast-enhanced microCT and scanning electron microscopy, we investigated patterns in lamellar morphology based on lamellar position along the olfactory rosette in Pacific spiny dogfish (Squalus suckleyi) and spotted ratfish (Hydrolagus colliei). We describe the gross olfactory rosette anatomy and lamellar microstructure of both species. We also put forth a new method, combining 3D morphological microCT data with 2D SEM microstructure data to better approximate lamellar sensory surface area. We found that in both species, lamellae in the center of the rosette were larger with more secondary folds. However, we found no significant differences in lamellar sensory surface area among lamellar positions. Previously, differences in lamellar sensory morphology have been tied to the internal fluid dynamics of the olfactory chamber. It is possible that the internal flow dynamics of these species are like other chondrichthyan models, where water flow patterns differ in the lateral vs the medial part of the organ, and the consistent distribution of sensory tissue does not correspond to this flow. Alternatively, the olfactory morphology of these species may result in uniform flow patterns throughout the olfactory chamber, correlating with the consistent distribution of sensory tissue throughout the organ. This study emphasizes that further investigations into chondrichthyan fluid dynamics is paramount to any future studies on the correlations between distribution of sensory tissues and water flow. 

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4. Mapping the Microstructure and Striae of the Human Olfactory Tract with Diffusion MRI

   https://doi.org/10.1523/JNEUROSCI.1552-21.2021  

   Echevarria-Cooper, Shiloh L.; Zhou, Guangyu; Zelano, Christina; Pestilli, Franco; Parrish, Todd B.; Kahnt, Thorsten (January 2022, The Journal of Neuroscience)

   The human sense of smell plays an important role in appetite and food intake, detecting environmental threats, social interactions, and memory processing. However, little is known about the neural circuity supporting its function. The olfactory tracts project from the olfactory bulb along the base of the frontal cortex, branching into several striae to meet diverse cortical regions. Historically, using diffusion magnetic resonance imaging (dMRI) to reconstruct the human olfactory tracts has been prevented by susceptibility and motion artifacts. Here, we used a dMRI method with readout segmentation of long variable echo-trains (RESOLVE) to minimize image distortions and characterize the human olfactory tracts in vivo . We collected high-resolution dMRI data from 25 healthy human participants (12 male and 13 female) and performed probabilistic tractography using constrained spherical deconvolution (CSD). At the individual subject level, we identified the lateral, medial, and intermediate striae with their respective cortical connections to the piriform cortex and amygdala (AMY), olfactory tubercle (OT), and anterior olfactory nucleus (AON). We combined individual results across subjects to create a normalized, probabilistic atlas of the olfactory tracts. We then investigated the relationship between olfactory perceptual scores and measures of white matter integrity, including mean diffusivity (MD). Importantly, we found that olfactory tract MD negatively correlated with odor discrimination performance. In summary, our results provide a detailed characterization of the connectivity of the human olfactory tracts and demonstrate an association between their structural integrity and olfactory perceptual function. SIGNIFICANCE STATEMENT This study provides the first detailed in vivo description of the cortical connectivity of the three olfactory tract striae in the human brain, using diffusion magnetic resonance imaging (dMRI). Additionally, we show that tract microstructure correlates with performance on an odor discrimination task, suggesting a link between the structural integrity of the olfactory tracts and odor perception. Lastly, we generated a normalized probabilistic atlas of the olfactory tracts that may be used in future research to study its integrity in health and disease. 

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5. Sensory input to cortex encoded on low-dimensional periphery-correlated subspaces

   https://doi.org/10.1093/pnasnexus/pgae010  

   Barreiro, Andrea K; Fontenele, Antonio J; Ly, Cheng; Raju, Prashant C; Gautam, Shree Hari; Shew, Woodrow L (December 2023, PNAS Nexus)

   Klann, Eric (Ed.)

   Abstract As information about the world is conveyed from the sensory periphery to central neural circuits, it mixes with complex ongoing cortical activity. How do neural populations keep track of sensory signals, separating them from noisy ongoing activity? Here, we show that sensory signals are encoded more reliably in certain low-dimensional subspaces. These coding subspaces are defined by correlations between neural activity in the primary sensory cortex and upstream sensory brain regions; the most correlated dimensions were best for decoding. We analytically show that these correlation-based coding subspaces improve, reaching optimal limits (without an ideal observer), as noise correlations between cortex and upstream regions are reduced. We show that this principle generalizes across diverse sensory stimuli in the olfactory system and the visual system of awake mice. Our results demonstrate an algorithm the cortex may use to multiplex different functions, processing sensory input in low-dimensional subspaces separate from other ongoing functions. 

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