The biological foundation of mental imagery is not fully understood. Studies using
fMRI have shown that the
lateral geniculate nucleus and the
V1 area of the
visual cortex are activated during mental imagery tasks.
Ratey writes: The
visual pathway is not a one-way street. Higher areas of the
brain can also send visual input back to
neurons in lower areas of the visual cortex. [...] As humans, we have the ability to see with the mind's eye—to have a perceptual experience in the absence of visual input. For example,
PET scans have shown that when subjects, seated in a room, imagine they are at their front door starting to walk either to the left or right, activation begins in the
visual association cortex, the
parietal cortex, and the
prefrontal cortex—all higher
cognitive processing centers of the brain. A biological basis for mental imagery is found in the deeper portions of the brain below the
neocortex. In a large study with 285 participants, Tabi, Maio, Attaallah, et al. (2022) investigated the association between an established measure of visual mental imagery,
Vividness of Visual Imagery Questionnaire (VVIQ) scores, and volumes of brain structures including the
hippocampus,
amygdala,
primary motor cortex,
primary visual cortex and the
fusiform gyrus Tabi et al. (2022) found significant positive correlations between visual imagery vividness and the volumes of the hippocampus and primary visual cortex. Significant positive correlations were also obtained between VVIQ scores and hippocampal structures including Bilateral CA1, CA3, CA4 and Granule Cell (GC) and Molecular Layer (ML) of the Dentate Gyrus (DG). Follow-up analysis revealed that visual imagery was in particular correlated with the four subfields presented in the above illustration. Furthermore, the
pineal gland is a hypothetical candidate for producing a mind's eye.
Rick Strassman and others have postulated that during
near-death experiences (NDEs) and
dreaming, the gland might secrete the hallucinogenic chemical
N,N-Dimethyltryptamine (DMT) to produce internal visuals when external sensory data is
occluded. However, this hypothesis has yet to be fully supported with
neurochemical evidence and plausible mechanism for DMT production. The condition where a person lacks mental imagery is called
aphantasia. The term was first suggested in a 2015 study. Common examples of mental images include
daydreaming and the mental visualization that occurs while reading a book. Another is of the pictures summoned by athletes during training or before a competition, outlining each step they will take to accomplish their goal. When a musician hears a song, they can sometimes "see" the song notes in their head, as well as hear them with all their tonal qualities. This is considered different from an after-effect, such as an
afterimage. Calling up an image in our minds can be a voluntary act, so it can be characterized as being under various degrees of conscious control. There are several theories as to how mental images are formed in the mind. These include the
dual-code theory, the propositional theory, and the functional-equivalency hypothesis. The dual-code theory, created by
Allan Paivio in 1971, is the theory that we use two separate codes to represent information in our brains: image codes and verbal codes. Image codes are things like thinking of a picture of a dog when you are thinking of a dog, whereas a verbal code would be to think of the word "dog". Another example is the difference between thinking of abstract words such as
justice or
love and thinking of concrete words like
elephant or
chair. When abstract words are thought of, it is easier to think of them in terms of verbal codes—finding words that define them or describe them. With concrete words, it is often easier to use image codes and bring up a picture of a
human or
chair in your mind rather than words associated or descriptive of them. The propositional theory involves storing images in the form of a generic propositional code that stores the meaning of the concept not the image itself. The propositional codes can either be descriptive of the image or symbolic. They are then transferred back into verbal and visual code to form the mental image. The functional-equivalency hypothesis is that mental images are "internal representations" that work in the same way as the actual perception of physical objects. In other words, the picture of a dog brought to mind when the word
dog is read is interpreted in the same way as if the person was observing an actual dog before them. Research has occurred to designate a specific neural correlate of imagery; however, studies show a multitude of results. Most studies published before 2001 suggest neural correlates of visual imagery occur in
Brodmann area 17. Auditory performance imagery have been observed in the premotor areas, precunes, and medial
Brodmann area 40. Auditory imagery in general occurs across participants in the temporal voice area (TVA), which allows top-down imaging manipulations, processing, and storage of audition functions. Olfactory imagery research shows activation in the anterior piriform cortex and the posterior piriform cortex; experts in olfactory imagery have larger gray matter associated to olfactory areas. Tactile imagery is found to occur in the dorsolateral prefrontal area, inferior frontal gyrus, frontal gyrus, insula, precentral gyrus, and the medial frontal gyrus with basal ganglia activation in the ventral posteriomedial nucleus and putamen (hemisphere activation corresponds to the location of the imagined tactile stimulus). Research in gustatory imagery reveals activation in the anterior insular cortex, frontal operculum, and prefrontal cortex. A meta-analysis of neuroimagery studies revealed significant activation of the bilateral dorsal parietal, interior insula, and left inferior frontal regions of the brain. Causal evidence from neurological patients with brain lesions demonstrates that vivid visual mental imagery is possible even when occipital visual areas are lesioned or disconnected from more anterior cortex. Visual mental imagery can instead be impaired by left temporal damage. Consistent with these findings, a meta-analysis of 27 neuroimaging studies demonstrated imagery-related activity in a region of the left ventral temporal cortex, which was dubbed the Fusiform Imagery Node. An additional Bayesian analysis excluded a role for occipital cortex in visual mental imagery, consistent with the evidence from neurological patients. Imagery has been thought to cooccur with perception; however, participants with damaged sense-modality receptors can sometimes perform imagery of said modality receptors. Neuroscience with imagery has been used to communicate with seemingly unconscious individuals through fMRI activation of different neural correlates of imagery, demanding further study into low quality consciousness. A study on one patient with one
occipital lobe removed found the horizontal area of their visual mental image was reduced. ==Neural substrates of visual imagery==