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Friday, October 26, 2018

Interoception

From Wikipedia, the free encyclopedia

Interoception is involved in many different physiological
systems like the cardiorespiratory system, gastrointestinal
system, nociceptive system, endocrine and immune systems

Interoception is contemporarily defined as the sense of the internal state of the body. It encompasses the brain’s process of integrating signals relayed from the body into specific subregions—like the brainstem, thalamus, insula, somatosensory, and anterior cingulate cortex—allowing for a nuanced representation of the physiological state of the body. This is important for maintaining homeostatic conditions in the body and, potentially, aiding in self-awareness.

Interoceptive signals are projected to the brain via a diversity of neural pathways that allow for the sensory processing and prediction of internal bodily states. Misrepresentations of internal states, or a disconnect between the body’s signals and the brain’s interpretation and prediction of those signals, have been suggested to underlie some mental disorders such as anxiety, depression, panic disorder, anorexia nervosa, bulimia nervosa, posttraumatic stress disorder (PTSD), obsessive compulsive disorder (OCD), autism spectrum disorders, somatic symptom disorder, and illness anxiety disorder.

The contemporary definition of interoception is not synonymous with the term “visceroception”. Visceroception refers to the perception of bodily signals arising specifically from the viscera: the heart, lungs, stomach, and bladder, along with other internal organs in the trunk of the body. This does not include organs like the brain and skin. Interoception encompasses visceral signaling, but more broadly relates to all physiological tissues that relay a signal to the central nervous system about the current state of the body. Interoceptive signals are transmitted to the brain via multiple pathways including (1) the lamina I spinothalamic pathway, (2) the classical viscerosensory pathway, (3) the vagus nerve and glossopharyngeal nerve, (4) chemosensory pathways in the blood, and (5) somatosensory pathways from the skin.

Interoceptive signals arise from many different physiological systems of the body. The most commonly studied system is cardiovascular interoception which is typically measured by directing attention towards the sensation of the heartbeat during various tasks. Other physiological systems integral to interoceptive processing include the respiratory system, gastrointestinal and genitourinary systems, nociceptive system, thermoregulatory system, endocrine and immune systems. Soft cutaneous touch is another sensory signal often included within the interoceptive processing system.

History and etymology

Early to mid-1900s

Interoception received increased visibility in the 21st century, but the concept was originally introduced by the Nobel Laureate Sir Charles S. Sherrington in 1906. Sherrington referred to interoception (although never stating the term, using “interoceptive” instead) as a way to describe receptors in the body based on their location and function. Here, interoception was confined to the viscera, excluding all receptors and information from the body that would have been considered “exteroceptive” or “proprioceptive.” In Sherrington’s model, exteroceptive receptors received information from outward stimuli, like light, touch, sound, and odor. He classified temperature and nociception as exteroceptive sensations as well; however, these have now been regarded as having interoceptive qualities. He further divided the internal milieu of the body by its somatic and autonomic functions. Here, proprioceptors were localized to skeletal tissue, which control voluntary movement. Interoceptors, a term which has lost prevalence in modern literature, were thus confined to visceral involuntary smooth muscle (e.g. surrounding blood vessels).

Many experiments were conducted in the 1950s and 1960s regarding interoceptive processing. However, research did not start immediately after Sherrington’s discussion of interoceptors because a book by John Newport Langley was published stating that the autonomic nervous system only used efferent (brain-to-body) signaling to implement its functions. This narrowed perspective halted research on interoceptive receptors for many years. Once it became apparent that interoceptive receptors are present in many tissues of the body other researchers began to investigate afferent body-to-brain signals, mainly by conducting animal experiments to see if interoceptive conditioning was possible. Using principles of Pavlovian conditioning, different physiological systems in dogs were perturbed to elicit a conditioned response to food. For example, in one experiment, dogs’ pelvises were distended using infusions of solution when food was presented to them. After rounds of pairing the two, salivation occurred without presenting food once the pelvis was distended. Interoceptive conditioning studies like this illustrated that interoceptive sensations may be important for learned behavior and emotion.

Mid-1900s to 2000

This graph shows the number of articles that reference the term “interoception” specifically from 1905 to 2015. A clear increase
in the number of publications per year on the topic is seen in the
21st century

The late 1950s and the 1960s saw an increased interest in interoception based on the number of publications released during that time period that referenced the term. This increase has been referred to as the “biofeedback blip,” where researchers examined the ability of a person to gain control over autonomic functions as a method of treatment for varying conditions.

Interoception did not gain widespread popularity within the scientific community until the mid- to late-twentieth century. Some researchers chose to use the term visceroceptor and interoceptor interchangeably, in line with Sherrington’s definition of the term; some combined proprioceptive and visceroceptive information into one category - interoception - based on physiological data about the lack of differences in nerve impulses, and some proposed that interoception is composed of more than just endogenous (internal) stimuli. There is ongoing debate about which sensory signals could or should be classified as "interoceptive."

During the 1980s, psychophysiologists began to examine cardiovascular interoception extensively, introducing several different tasks for studying heartbeat perception: heartbeat counting, heartbeat tapping, and heartbeat detection. Psychiatrists were also beginning to look at the effects of pharmacological stimulation on panic disorder symptoms as well. This led to a growing interest in interoception during this time period, including the development of theoretical models on the integration of interoceptive information within the body over time.

2000 and on

The twenty-first century has seen an exponential increase in publications on the topic of interoception, and a recognition of the multifaceted nature of this concept. With a renewed interest in research, different ideas about interoception have emerged. One definition widens the concept to encompass “the skin and all that is underneath the skin” and the perception and function of bodily activity to more fully understand psychosomatic processes. In a similar vein, neuroanatomists hoping to find the anatomical basis of interoceptive functioning have stated the existence of a homeostatic pathway from the body to the brain that represents “the physiological status of all tissues in the body” and that this mapping onto the brain provides an individual with subjective feeling states which are critical for human emotion and self-awareness.

For example, interoception is the fundament of the modern view on allostasis and allostatic load. The regulatory model of allostasis claims that the brain’s primary role as an organ is the predictive regulation of internal sensations. Predictive regulation refers to the brain’s ability to anticipate needs and prepare to fulfill them before they arise. Therefore, in this model, the brain is responsible for efficient regulation of its internal milieu.

Interoception is sometimes generally referred to as “the perception of internal body states” although there are many interoceptive processes in the body which are not perceived. Importantly, interoception is made possible through a process of “integrating the information coming from inside the body into the central nervous system.” This definition deviates from Sherrington’s original proposition, but exemplifies the dynamic and widening breadth of interoception as a concept in modern literature.

Facets of interoception

This table defines many of the different facets or components of interoception

Although interoception as a term has more recently gained increased popularity, different aspects of it have been studied since the 1950s. These include the features of attention, detection, magnitude, discrimination, accuracy, sensibility, and self-report. Despite not using the word “interoception” specifically, many publications in the physiology and medical fields have focused on understanding interoceptive information processing in different organ systems. Attention describes the ability to observe sensations within the body, it can be directed voluntarily in a "top down" manner or it can be attracted involuntarily in a "bottom up" manner. Detection reflects the presence or absence of a conscious report of interoceptive stimuli, like a heartbeat or growling stomach. Magnitude is the intensity of the stimulus, or how strongly the stimuli is felt. Discrimination describes the ability to localize interoceptive stimuli in the body to specific organs and differentiate them from other bodily stimuli that also occur, like distinguishing between a heart which is beating hard from an upset stomach. Accuracy (or sensitivity) refers to how precisely and correctly an individual can monitor specific interoceptive processes. Self-report is itself multifaceted. It describes the ability to reflect on interoceptive experiences occurring over different periods of time, make judgments about them, and describe them. Brain-body interactions can also be studied using neuroimaging techniques to map functional interactions between brain and peripheral signals. Although all of these components of interoception have been studied since the mid-twentieth century, they have not been brought together under the umbrella-term “interoception” until more recently. The term "interoceptive awareness" is also frequently used to encompass any (or all) of the different interoception features that are accessible to conscious self-report. This multifaceted approach offers a unified way of looking at interoceptive functioning and its different features, it clarifies the definition of interoception itself, and it informs structured ways of assessing interoceptive experiences in an individual.

This graph shows the number of articles published on
interoception vs. articles published on interoceptive facets
without directly referencing the term from 1905-2015. The
timeline starts one year before the publication of Charles
Sherrington’s book, “The integrative action of the nervous
system,” which introduced “interoception"

Interoceptive physiology

Cardiovascular system

This table illustrates the most common tasks that are used to assess cardiovascular interoception, broken down by the corresponding facets that they test. The exemplars at the bottom refer to specific studies or researchers who developed the task.

Cardiac interoception has been widely studied as a method of evaluating interoceptive sensation. This is done using different tasks including heartbeat counting, heartbeat tapping, heartbeat detection and heartbeat attention tasks. Heartbeat counting tasks ask participants to count the number of felt heartbeats during short time periods. Their reported count is then compared with the actual count obtained with an electrocardiogram. This measures the participant’s attention to his or her own heartbeat, the accuracy with which that is perceived, and the ability of the participant to report that measurement; however, results can be influenced by the participant’s preexisting knowledge of his or her heart rate and an insensitivity to heart rate change. Heartbeat detection tasks work by providing a participant with a musical tone which is played simultaneously or non-simultaneously with one’s heartbeat, asking the participant to report whether it is simultaneous or not with the tones. Heartbeat detection is commonly used because of its ability discern an individual’s performance above chance levels, so-called "good detectors." However, such detection rates among participants for this task are usually only 35%. It also measures the participant’s attention, detection, discrimination, accuracy and self-report of the interoceptive process. Heartbeat attention tasks are the most minimalistic, and involve simply the top-down direction of attention towards an interoceptive sensation such as the heartbeat, breath, or stomach. Most perceptions of heartbeat sensations usually occur during a time of homeostatic perturbation, such as when the state of the body changes from external or internal influences such as physical exertion or elevated arousal states (e.g., riding a roller coaster, watching a scary movie, public speaking anxiety, or having a panic attack). For this reason, cardiac interoception is also sometimes studied by inducing perturbations of bodily state. This can be done pharmacologically using adrenaline-like drugs, such as isoproterenol, which mimics activation of the sympathetic nervous system, resulting in increased heart rate and respiration rate, similar to the “fight-or-flight” response. This approach provides a physiological basis for understanding psychiatric and neurological disorders that are characterized by heightened sympathetic nervous system activity.

Respiratory and chemoreceptive system

Respiratory perception can differ from other interoceptive physiological symptoms because of an individual’s ability to exert voluntary control over the system with controlled breathing or breathing exercises. This system is often measured using restrictive breathing loads and/or CO2 inhalation, which are designed to mimic labored breathing sensations. Dyspnea, or difficulty breathing, is a commonly felt sensation associated with panic attacks; however, due to the voluntary control of breathing, this domain of interoception usually requires implementation of much more elaborate experimental controls to quantify in comparison to cardiac interoception.

Gastrointestinal and genitourinary systems

Common interoceptive sensations related to the gastrointestinal and genitourinary systems are hunger and fullness. These are homeostatic signals that tell an individual when to eat and when to stop eating. The dorsal mid-insula appears to be integral in taste processing during gastrointestinal interoceptive attention tasks. Rectal and bladder distensions are used as a method to perturb the homeostatic environment of the gastrointestinal and genitourinary systems, using placement of balloon catheters which can be inflated to achieve different stimulus intensities. Associative fear learning paradigms have been used to study how innocuous signals might lead to abnormal states of gastrointestinal hypersensitivity and anxiety. Biofeedback therapy has been used for individuals with impaired gastrointestinal interoception, showing positive outcomes for some patients.

Nociceptive system

Nociception refers to the receiving and processing of pain inducing stimuli by the central nervous system. Functional brain imaging studies during painful stimulation of the skin with heated probes, during mechanical compression, and electric shock have suggested that the insular cortex is prominently activated during pain processing. Thus while pain was once thought of as an exteroceptive sensation, based on functional imaging and anatomical evidence it is now understood that it has an interoceptive component.

Thermoregulatory system

Temperature and pain are thought to be represented as “feelings” of coolness/warmness and pleasantness/unpleasantness in the brain. These sensory and affective characteristics of thermoregulation may motivate certain behavioral responses depending on the state of the body (for example, moving away from a source of heat to a cooler space). Such perturbations in the internal homeostatic environment of an organism are thought to be key aspects of a motivational process giving rise to emotional states, and have been proposed to be represented principally by the insular cortex as feelings. These feelings then influence drives when the anterior cingulate cortex is activated.

Endocrine and immune systems

The endocrine and immune systems are necessary body systems that aid in allostasis and homeostatic control. Imbalances in these systems, along with other genetic and social factors, may be linked to interoceptive dysregulation in depression. These increased allostatic changes may cause a hyperawareness of interoceptive signaling and a hypo-awareness of exteroceptive signaling in depression patients.

Soft touch

Soft touch refers to the stimulation of slow, unmyelinated C Tactile afferents. This is accompanied by a sense of pleasantness, and has been likened to other interoceptive modalities like thermoregulation and nociception because of the similarities in anatomical function. Soft touch activates the insula rather than the somatosensory cortex, indicating that it has an affective importance absent in Aβ fibers. Since soft touch utilizes a separate pathway, it may have a social relevancy, allowing the body to separate the “noise” of outward stimuli from stimuli that evokes an affective feeling.

Neuroanatomical pathways

Multiple neural pathways relay information integral to interoceptive processing from the body to the brain. these include the lamina I spinothalamic pathway, the visceroceptive pathway, and the somatosensory pathway.

Lamina I spinothalamic pathway

The lamina I spinothalamic pathway is commonly known for carrying information to the brain about temperature and pain, but it has been suggested to more broadly relay all information about the homeostatic condition of the body:

Visceroceptive pathway

The visceroceptive pathway relays information about visceral organs to the brain:

Somatosensory pathway

The somatosensory pathway relays information about proprioception and discriminative touch to the brain through different receptors in the skin:

Cortical processing of interoception

Thalamus

The thalamus receives signals from sympathetic and parasympathetic afferents during interoceptive processing. The ventromedial posterior nucleus (VMpo) is a subregion of the thalamus which receives sympathetic information from lamina I spinothalamic neurons. The human VMpo is much larger than that of primates and sub-primates and is important for processing of nociceptive, thermoregulatory, and visceral sensations. The ventromedial basal nucleus (VMb) receives parasympathetic information from visceral and gustatory systems.

Insular cortex


This image divides the insula into its anterior, mid, and
posterior regions, with each being denoted by different
colors.

The insula is critically involved in the processing, integration, and cortical representation of visceral and interoceptive information. Lamina I spinothalamic and vagal afferents project via the brainstem and thalamus to the posterior and mid dorsal insula respectively. From there, information travels to the posterior and mid-insula, which combines visceral and somatosensory information. The insula is also activated during a variety of exteroceptive and affective tasks. The insula is considered to be a "hub" region because it has an extremely high number of connections with other brain areas, suggesting it may be important for an integration of lower-level physiological information and salience.

The insula connects to many regions in the brain and is highly
involved in many homeostatic functions.

Anterior insular cortex

The anterior insular cortex (AIC) is involved in the representation of “cognitive feelings” which arise from the moment-to-moment integration of homeostatic information from the body. These feelings engender self-awareness by creating a sentient being (someone able to feel and perceive) aware of bodily and cognitive processing.

Cytoarchitecture and granulation

The insular cortex differs cytoarchitecturally based on its
anterior, mid, and posterior regions. The posterior insular
cortex is granular, the mid insular cortex is dysgranular (or
slightly granulated) and the anterior insular cortex has no
granulation whatsoever.

The insula contains three major subregions defined by the presence or absence of a granule cell layer: granular, dysgranular (slightly granulated) agranular. Each of these portions of the insular cortex are important for different levels of functional connectivity. Information from the thalamus is projected to all three regions. Those with increased granulation are considered to be capable of receiving sensory input.

Anterior cingulate cortex

The anterior cingulate cortex (ACC) plays a significant role in motivation and the creation of emotion. An emotion can be seen as comprising both a feeling and a motivation based on that feeling. According to one view, the “feeling” is represented in the insula, while the “motivation” is represented in the ACC. Many interoceptive tasks activate the insula and ACC together, specifically tasks that elicit strong aversive feeling states like pain.

Somatosensory cortex

The sensory motor cortex provides an alternative pathway for sensing interoceptive stimuli. Although not following the conventional pathway for interoceptive awareness, skin afferents which project to the primary and secondary somatosensory cortices provide the brain with information regarding bodily information. This area of the brain is commonly engaged by gastrointestinal distension and nociceptive stimulation, but it likely plays a role in representing other interoceptive sensations as well. In one study, a patient with bilateral insula and ACC damage was given isoproterenol as a method of exciting the cardiovascular system. Despite damage to putative interoceptive areas of the brain, the patient was able to perceive his heartbeat with similar accuracy compared to healthy individuals; however, once lidocaine was applied to the patient’s chest over the region of maximum cardiac sensation and the test was run again, the patient did not sense any change in heartbeat whatsoever. This suggested that somatosensory information from afferents innervating the skin outside of the heart may provide information to the brain about the heart’s pounding through the somatosensory cortex.

Interoception and emotion

The relationship between interoception and emotional experience is an intimate one. In the late 19th century, Charles Darwin noted and discussed the involvement of sensations from the viscera by describing similarities between humans and animals reactions to fear in his book, The Expression of Emotions in Man and Animals. Later, William James and Carl Lange developed the James-Lange theory of emotion, which states that bodily sensations provide the critical basis for emotional experience. The somatic marker hypothesis, proposed by Antonio Damasio, expands upon the James-Lange theory and posits that decisions and the ensuing behaviors are optimally guided by physiological patterns of interoceptive and emotional information. Ensuing models focusing on the neurobiology of feelings states emphasized that the brain’s mapping of different physiological body states are the critical ingredients for emotional experience and consciousness. In another model, A.D. Craig argues that the intertwining of interoceptive and homeostatic processes is responsible for initiating and maintaining motivational states and engendering human self-awareness.

Interoception and mental health

Disturbances of interoception occur prominently and frequently in psychiatric disorders. These symptom fluctuations are often observed during the most severe expression of dysfunction, and they figure prominently in diagnostic classification of several psychiatric disorders. A few typical examples are reviewed next.

Panic disorder

Palpitations and dyspnea are hallmarks of panic attacks. Studies have shown that panic disorder patients report a heightened experience of interoceptive sensations, but these studies have failed to clarify whether this is simply due to their systematic bias toward describing such feelings. However, other studies have shown that panic disorder patients feel heartbeat sensations more intensely when the state of the body is perturbed by pharmacological agents, suggesting they exhibit heightened sensitivity to experiencing interoceptive sensations.

Generalized anxiety disorder

Patients with generalized anxiety disorder (GAD) frequently report being bothered by interoceptive feelings of muscle tension, headaches, fatigue, gastrointestinal complaints, and pain.

Posttraumatic stress disorder

Functional neuroimaging studies have shown that posttraumatic stress disorder (PTSD) patients exhibit a decreased activation in the right anterior insula, a region of the brain that is largely responsible for identifying the mismatch between cognitive and interoceptive states. Further, because PTSD patients have shown decreased activation within many nodes of the lamina I homeostatic pathway—a pathway through which the thalamus sends interoceptive information to the anterior insula and anterior cingulate—it has been suggested that PTSD patients experience reduced interoceptive awareness.

Anxiety disorders

The broad consensus of studies investigating the link between interoceptive awareness and anxiety disorders is that people with anxiety disorders experience heightened awareness of and accuracy in identifying interoceptive processes. Functional imaging studies provide evidence that people with anxiety disorders experience heightened interoceptive accuracy, suggested by hyperactivation in the anterior cingulate cortex—a region of the brain associated with interoception—in several different kinds of anxiety disorders. The insula has been suggested to be abnormal in a large scale study across anxiety disorders in general. Other studies have found that interoceptive accuracy is increased in these patients, as evidenced by their superior ability in heartbeat detection tasks in comparison to healthy controls.

Anorexia nervosa

Anorexia nervosa (AN) has been associated with interoceptive disturbances. Patients with AN often develop insensitivity to interoceptive cues of hunger, and yet are highly anxious and report disturbed interoceptive experiences, both inside and out. While AN patients concentrate on distorted perceptions of their body exterior in fear of weight gain, they also report altered physical states within their bodies, such as indistinct feelings of fullness, or an inability to distinguish emotional states from bodily sensations in general (called alexithymia).

Bulimia nervosa

Studies suggest that patients acutely suffering from bulimia nervosa (BN) exhibit heightened interoceptive accuracy, but that some patients who have recovered from the disorder show reduced interoceptive awareness under resting physiological conditions. Further, BN patients consistently report reduced sensitivity to many other kinds of internal and external sensations, exhibiting increased thresholds to heat pain compared to healthy subjects and an increased gastric capacity. Neuroimaging literature suggests a pattern of heightened interoceptive awareness in patients with BN based on increased activity and volume in the insula and anterior cingulate cortex—regions associated with interoception and taste processing—when looking at food.

Major depressive disorder

Major depressive disorder (MDD) has been theoretically linked to interoceptive dysfunction. Studies have shown that women with MDD are less accurate on heartbeat counting tasks than are men with MDD and that, in general, patients with MDD are less accurate at counting heartbeat than are patients with panic or anxiety disorders. However, patients with MDD do not always exhibit reduced cardiac interoceptive accuracy; depressed patients experiencing high levels of anxiety will actually be more accurate on heartbeat detection tasks than depressed patients with lower levels of anxiety.

Somatic symptom disorders

Patients with somatic symptom disorders score lower on heartbeat detection tasks than healthy controls, suggesting that interoceptive accuracy is poor in psychosomatic disorders. It has also been found that patients with psychosomatic disorders who are anxious or stressed report physical symptom discomfort at lower heart rates during exercise treadmill tests, implying poorer interoceptive distress tolerance in somatic symptom disorders with comorbid psychiatric conditions.

Obsessive compulsive disorder

Results from a study investigating the relationship between obsessive compulsive disorder (OCD) and internal body signals found that patients with OCD were more accurate on a heartbeat perception task than healthy controls and anxiety patients heightened interoceptive awareness.

Autism spectrum disorder

Patients with autism spectrum disorder (ASD) may have poorer interoceptive awareness than [control] subjects. It is hypothesized that this decrease in interoceptive accuracy is due to alexithymia, which is often associated with ASD. However, it has also been found that children with ASD actually show greater interoceptive sensitivity than [control subjects] when measured over a long period of time. Further investigation into the relationship between interoception and ASD is needed in order to fully understand the interoceptive aspect of the disorder.

Current theories of interoceptive processing

Embodied predictive interoception coding (EPIC)

The EPIC model proposes a method of understanding the brain’s response to stimuli contrary to the classic "stimulus-response" model. The classical view of information processing is that when a peripheral stimulus provided information to the central nervous system, it was processed in the brain, and a response was elicited. The EPIC model deviates from this and proposes that the brain is involved in a process of active inference, that is, assiduously making predictions about situations based on previous experiences. These predictions, when coupled with incoming sensory signals, allow the brain to compute a prediction error. Interoceptive prediction errors signal the occurrence of discrepancies within the body, which the brain attempts to minimize. This can be done by 1) modifying the predictions through brain-related pathways, 2) altering the body position/location in order to better align incoming sensory signals with the prediction, or 3) altering the brain’s method of receiving incoming stimuli. Interoceptive prediction error signals are a key component of many theories of interoceptive dysfunction in physical and mental health.

Research and treatments

As attention on interoception increases among the scientific community, new research methods and treatment tactics are beginning to emerge. Ongoing research in interoception has shown the importance of perturbing interoceptive systems. This allows researchers the ability to document the effects of non-baseline states, which occur during times of panic or anxiety. It also provides the participant the ability to gauge the intensity of sensations within the body. This can be done through pharmacological interventions, balloon distensions, or respiratory breathing loads depending on the interoceptive system of interest.

An open float pool

Another research method used to study interoception is specialized flotation environments. Floating removes external stimuli so that individuals can more easily focus on the interoceptive sensations within their bodies. One idea with floating is that over many float sessions, patients with different kinds of disorders may learn to become more attuned or tolerant of their interoceptive sensations not only in the float tank but also in their everyday lives.

Whole body hyperthermia may provide a new treatment technique for major depressive disorder. It is thought that reducing one of the bodily symptoms of depression, which is increased inflammation, using whole body hyperthermia will also reduce depressive feelings represented in the brain. In theory, these techniques will help patients better attune themselves to their interoceptive sensations, allowing them a better understanding of what occurs in their bodies.

Acupuncture is an alternative treatment type for many people suffering from anxiety and depression. Typically, it is self-prescribed by patients; however, results are inconclusive on its ability to manage symptoms of depression. Recently, massage therapy has been shown to have the ability to reduce symptoms of generalized anxiety disorder.

Meditation and mindfulness have been looked into as possible techniques to enhance interoceptive awareness based on their tendency to redirect focus within oneself. However, studies show that even though meditation and mindfulness practices promote attention to interoceptive sensations, they do not clearly increase interoceptive awareness in specific domains such as breath or body [null monitoring.]

Although a universal definition of interoception has not been reached, research on interoception and psychiatric disorders has shown a link between interoceptive processing and mental disorders. It has been proposed that exposure therapy, commonly used among anxiety disorders, may provide a basis for a model of interoceptive exposure therapy that could be incorporated into treatment plans of different psychiatric disorders. One proposal states that multiple interoceptive challenges assessing different physiological systems could provide diagnosticians with the ability to create an “interoceptive profile” for a specific individual, creating a patient-specific treatment plan.

Insular cortex

From Wikipedia, the free encyclopedia
Insular cortex
Sobo 1909 633.png
The insula of the right side, exposed by
removing the opercula
 
Gray717.png
Coronal section of brain immediately in
front of pons. (Insula labeled at upper right.)
Details
Part of cerebral cortex of brain
Artery Middle cerebral
Identifiers
Latin Cortex insularis
NeuroNames 111
NeuroLex ID birnlex_1117
TA A14.1.09.149
FMA 67329

 In each hemisphere of the mammalian brain the insular cortex (also insula and insular lobe) is a portion of the cerebral cortex folded deep within the lateral sulcus (the fissure separating the temporal lobe from the parietal and frontal lobes).

The insulae are believed to be involved in consciousness and play a role in diverse functions usually linked to emotion or the regulation of the body's homeostasis. These functions include compassion and empathy, perception, motor control, self-awareness, cognitive functioning, and interpersonal experience. In relation to these, it is involved in psychopathology.

The insular cortex is divided into two parts: the larger anterior insula and the smaller posterior insula in which more than a dozen field areas have been identified. The cortical area overlying the insula toward the lateral surface of the brain is the operculum (meaning lid). The opercula are formed from parts of the enclosing frontal, temporal, and parietal lobes.

Structure

Connections

The anterior part of the insula is subdivided by shallow sulci into three or four short gyri.
The anterior insula receives a direct projection from the basal part of the ventral medial nucleus of the thalamus and a particularly large input from the central nucleus of the amygdala. In addition, the anterior insula itself projects to the amygdala.

One study on rhesus monkeys revealed widespread reciprocal connections between the insular cortex and almost all subnuclei of the amygdaloid complex. The posterior insula projects predominantly to the dorsal aspect of the lateral and to the central amygdaloid nuclei. In contrast, the anterior insula projects to the anterior amygdaloid area as well as the medial, the cortical, the accessory basal magnocellular, the medial basal, and the lateral amygdaloid nuclei.

The posterior part of the insula is formed by a long gyrus.

The posterior insula connects reciprocally with the secondary somatosensory cortex and receives input from spinothalamically activated ventral posterior inferior thalamic nuclei. It has also been shown that this region receives inputs from the ventromedial nucleus (posterior part) of the thalamus that are highly specialized to convey homeostatic information such as pain, temperature, itch, local oxygen status, and sensual touch.

A human neuroimaging study using diffusion tensor imaging revealed that the anterior insula is interconnected to regions in the temporal and occipital lobe, opercular and orbitofrontal cortex, triangular and opercular parts of the inferior frontal gyrus. The same study revealed differences in the anatomical connection patterns between the left and right hemisphere.

The 'circular sulcus of insula' (or sulcus of Reil)is a semi-circular sulcus or fissure that separates the insula from the neighboring gyri of the operculum in the front, above, and behind.

Cytoarchitecture

The insular cortex has regions of variable cell structure or cytoarchitecture, changing from granular in the posterior portion to agranular in the anterior portion. The insula also receives differential cortical and thalamic input along its length. John Allman and his colleagues have shown that the anterior insular cortex contains a population of neurons, called spindle neurons. These are also called von Economo neurons, identified as characterising a distinctive subregion as the agranular frontal insula.

Development

The insular cortex is considered a separate lobe of the telencephalon by some authorities. Other sources see the insula as a part of the temporal lobe. It is also sometimes grouped with limbic structures deep in the brain into a limbic lobe. As a paralimbic cortex, the insular cortex is considered to be a relatively old structure.

Function

Multimodal sensory processing, sensory binding

Functional imaging studies show activation of the insula during audio-visual integration tasks.

Interoceptive awareness

There is evidence that, in addition to its base functions, the insula may play a role in certain higher-level functions that operate only in humans and other great apes. The spindle neurons found at a higher density in the right frontal insular cortex are also found in the anterior cingulate cortex, which is another region that has reached a high level of specialization in great apes. It has been speculated that these neurons are involved in cognitive-emotional processes that are specific to primates including great apes, such as empathy and metacognitive emotional feelings. This is supported by functional imaging results showing that the structure and function of the right frontal insula is correlated with the ability to feel one's own heartbeat, or to empathize with the pain of others. It is thought that these functions are not distinct from the lower-level functions of the insula but rather arise as a consequence of the role of the insula in conveying homeostatic information to consciousness. The right anterior insula aids interoceptive awareness of body states, such as the ability to time one's own heartbeat. Moreover, greater right anterior insular gray matter volume correlates with increased accuracy in this subjective sense of the inner body, and with negative emotional experience. It is also involved in the control of blood pressure, in particular during and after exercise, and its activity varies with the amount of effort a person believes he/she is exerting.

The insular cortex also is where the sensation of pain is judged as to its degree. Further, the insula is where a person imagines pain when looking at images of painful events while thinking about their happening to one's own body. Those with irritable bowel syndrome have abnormal processing of visceral pain in the insular cortex related to dysfunctional inhibition of pain within the brain.

Another perception of the right anterior insula is the degree of nonpainful warmth or nonpainful coldness of a skin sensation. Other internal sensations processed by the insula include stomach or abdominal distension. A full bladder also activates the insular cortex.

One brain imaging study suggests that the unpleasantness of subjectively perceived dyspnea is processed in the right human anterior insula and amygdala.

The cerebral cortex processing vestibular sensations extends into the insula, with small lesions in the anterior insular cortex being able to cause loss of balance and vertigo.

Other noninteroceptive perceptions include passive listening to music, laughter, and crying, empathy and compassion, and language.

Motor control

In motor control, it contributes to hand-and-eye motor movement, swallowing, gastric motility, and speech articulation. It has been identified as a "central command” centre that ensures that heart rate and blood pressure increase at the onset of exercise. Research upon conversation links it to the capacity for long and complex spoken sentences. It is also involved in motor learning and has been identified as playing a role in the motor recovery from stroke.

Homeostasis

It plays a role in a variety of homeostatic functions related to basic survival needs, such as taste, visceral sensation, and autonomic control. The insula controls autonomic functions through the regulation of the sympathetic and parasympathetic systems. It has a role in regulating the immune system.

Self

It has been identified as playing a role in the experience of bodily self-awareness, sense of agency, and sense body ownership.

Social emotions

The anterior insula processes a person's sense of disgust both to smells and to the sight of contamination and mutilation — even when just imagining the experience. This associates with a mirror neuron-like link between external and internal experiences.

In social experience, it is involved in the processing of norm violations, emotional processing, empathy, and orgasms.

The insula is active during social decision making. Tiziana Quarto et al. measured emotional intelligence (EI) (the ability to identify, regulate, and process emotions of themselves and of others) of sixty-three healthy subjects. Using fMRI EI was measured in correlation with left insular activity. The subjects were shown various pictures of facial expressions and tasked with deciding to approach or avoid the person in the picture. The results of the social decision task yielded that individuals with high EI scores had left insular activation when processing fearful faces. Individuals with low EI scores had left insular activation when processing angry faces.

Emotions

The insular cortex, in particular its most anterior portion, is considered a limbic-related cortex. The insula has increasingly become the focus of attention for its role in body representation and subjective emotional experience. In particular, Antonio Damasio has proposed that this region plays a role in mapping visceral states that are associated with emotional experience, giving rise to conscious feelings. This is in essence a neurobiological formulation of the ideas of William James, who first proposed that subjective emotional experience (i.e., feelings) arise from our brain's interpretation of bodily states that are elicited by emotional events. This is an example of embodied cognition.

In terms of function, the insula is believed to process convergent information to produce an emotionally relevant context for sensory experience. To be specific, the anterior insula is related more to olfactory, gustatory, viscero-autonomic, and limbic function, whereas the posterior insula is related more to auditory-somesthetic-skeletomotor function. Functional imaging experiments have revealed that the insula has an important role in pain experience and the experience of a number of basic emotions, including anger, fear, disgust, happiness, and sadness.

The anterior insular cortex (AIC) is believed to be responsible for emotional feelings, including maternal and romantic love, anger, fear, sadness, happiness, sexual arousal, disgust, aversion, unfairness, inequity, indignation, uncertainty, disbelief, social exclusion, trust, empathy, sculptural beauty, a ‘state of union with God’, and hallucinogenic state.

Functional imaging studies have also implicated the insula in conscious desires, such as food craving and drug craving. What is common to all of these emotional states is that they each change the body in some way and are associated with highly salient subjective qualities. The insula is well-situated for the integration of information relating to bodily states into higher-order cognitive and emotional processes. The insula receives information from "homeostatic afferent" sensory pathways via the thalamus and sends output to a number of other limbic-related structures, such as the amygdala, the ventral striatum, and the orbitofrontal cortex, as well as to motor cortices.

A study using magnetic resonance imaging found that the right anterior insula is significantly thicker in people that meditate. Other research into brain activity and meditation has shown an increase in grey matter in areas of the brain including the insular cortex.

Another study using voxel-based morphometry and MRI on experienced Vipassana meditators was done to extend the findings of Lazar et al., which found increased grey matter concentrations in this and other areas of the brain in experienced meditators.

The strongest evidence against a causative role for the insula cortex in emotion comes from Damasio et al. (2012)  which showed that a patient who suffered bilateral lesions of the insula cortex expressed the full complement of human emotions, and was fully capable of emotional learning.

Salience

Functional neuroimaging research suggests the insula is involved in two types of salience. Interoceptive information processing that links interoception with emotional salience to generate a subjective representation of the body. This involves, first, the anterior insular cortex with the pregenual anterior cingulate cortex (Brodmann area 33) and the anterior and posterior mid-cingulate cortices, and, second, a general salience network concerned with environmental monitoring, response selection, and skeletomotor body orientation that involves all of the insular cortex and the mid-cingulate cortex.

An alternative or perhaps complementary proposal is that the right anterior insular regulates the interaction between the salience of the selective attention created to achieve a task (the dorsal attention system) and the salience of arousal created to keep focused upon the relevant part of the environment (ventral attention system). This regulation of salience might be particularly important during challenging tasks where attention might fatigue and so cause careless mistakes but if there is too much arousal it risks creating poor performance by turning into anxiety.

Clinical significance

Progressive expressive aphasia

Progressive expressive aphasia is the deterioration of normal language function that causes individuals to lose the ability to communicate fluently while still being able to comprehend single words and intact other non-linguistic cognition. It is found in a variety of degenerative neurological conditions including Pick's disease, motor neuron disease, corticobasal degeneration, frontotemporal dementia, and Alzheimer's disease. It is associated with hypometabolism and atrophy of the left anterior insular cortex.

Addiction

A number of functional brain imaging studies have shown that the insular cortex is activated when drug abusers are exposed to environmental cues that trigger cravings. This has been shown for a variety of drugs, including cocaine, alcohol, opiates, and nicotine. Despite these findings, the insula has been ignored within the drug addiction literature, perhaps because it is not known to be a direct target of the mesocortical dopamine system, which is central to current dopamine reward theories of addiction. Research published in 2007 has shown that cigarette smokers suffering damage to the insular cortex, from a stroke for instance, have their addiction to cigarettes practically eliminated. These individuals were found to be up to 136 times more likely to undergo a disruption of smoking addiction than smokers with damage in other areas. Disruption of addiction was evidenced by self-reported behavior changes such as quitting smoking less than one day after the brain injury, quitting smoking with great ease, not smoking again after quitting, and having no urge to resume smoking since quitting. The study was conducted on average eight years after the strokes, which opens up the possibility that recall bias could have affected the results. More recent prospective studies, which overcome this limitation, have corroborated these findings This suggests a significant role for the insular cortex in the neurological mechanisms underlying addiction to nicotine and other drugs, and would make this area of the brain a possible target for novel anti-addiction medication. In addition, this finding suggests that functions mediated by the insula, especially conscious feelings, may be particularly important for maintaining drug addiction, although this view is not represented in any modern research or reviews of the subject.

A recent study in rats by Contreras et al. corroborates these findings by showing that reversible inactivation of the insula disrupts amphetamine conditioned place preference, an animal model of cue-induced drug craving. In this study, insula inactivation also disrupted "malaise" responses to lithium chloride injection, suggesting that the representation of negative interoceptive states by the insula plays a role in addiction. However, in this same study, the conditioned place preference took place immediately after the injection of amphetamine, suggesting that it is the immediate, pleasurable interoceptive effects of amphetamine administration, rather than the delayed, aversive effects of amphetamine withdrawal that are represented within the insula.

A model proposed by Naqvi et al. (see above) is that the insula stores a representation of the pleasurable interoceptive effects of drug use (e.g., the airway sensory effects of nicotine, the cardiovascular effects of amphetamine), and that this representation is activated by exposure to cues that have previously been associated with drug use. A number of functional imaging studies have shown the insula to be activated during the administration of drugs of abuse. Several functional imaging studies have also shown that the insula is activated when drug users are exposed to drug cues, and that this activity is correlated with subjective urges. In the cue-exposure studies, insula activity is elicited when there is no actual change in the level of drug in the body. Therefore, rather than merely representing the interoceptive effects of drug use as it occurs, the insula may play a role in memory for the pleasurable interoceptive effects of past drug use, anticipation of these effects in the future, or both. Such a representation may give rise to conscious urges that feel as if they arise from within the body. This may make addicts feel as if their bodies need to use a drug, and may result in persons with lesions in the insula reporting that their bodies have forgotten the urge to use, according to this study.

Subjective certainty in ecstatic seizures

A common quality in mystical experiences is a strong feeling of certainty which cannot be expressed in words. Fabienne Picard proposes a neurological explanation for this subjective certainty, based on clinical research of epilepsy. According to Picard, this feeling of certainty may be caused by a dysfunction of the anterior insula, a part of the brain which is involved in interoception, self-reflection, and in avoiding uncertainty about the internal representations of the world by "anticipation of resolution of uncertainty or risk". This avoidance of uncertainty functions through the comparison between predicted states and actual states, that is, "signaling that we do not understand, i.e., that there is ambiguity." Picard notes that "the concept of insight is very close to that of certainty," and refers to Archimedes' "Eureka!" Picard hypothesizes that during ecstatic seizures the comparison between predicted states and actual states no longer functions, and that mismatches between predicted state and actual state are no longer processed, blocking "negative emotions and negative arousal arising from predictive uncertainty," which will be experienced as emotional confidence. Picard concludes that "[t]his could lead to a spiritual interpretation in some individuals."

Other clinical conditions

The insular cortex has been suggested to have a role in anxiety disorders, emotion dysregulation, and anorexia nervosa.

History

The insula was first described by Johann Christian Reil while describing cranial and spinal nerves and plexi. Henry Gray in Gray's Anatomy is responsible for it being known as the Island of Reil.

Additional images

Equality (mathematics)

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