ABSTRACT
Itch is a protective/defensive function with divalent motivational drives. Itch itself elicits an unpleasant experience, which triggers the urge to scratch, relieving the itchiness. Still, it can also result in dissatisfaction when the scratch is too intense and painful or unsatisfactory due to insufficient scratch effect. Therefore, it is likely that the balance between the unpleasantness/pleasure and satisfaction/unsatisfaction associated with itch sensation and scratching behavior is determined by complex brain mechanisms. The physiological/pathological mechanisms underlying this balance remain largely elusive. To address this issue, we targeted the "reward center" of the brain, the nucleus accumbens (NAc), in which itch-responsive neurons have been found in rodents. We examined how neurons in the NAc are activated or suppressed during histamine-induced scratching behaviors in mice. The mice received an intradermal injection of histamine or saline at the neck, and the scratching number was analyzed by recording the movement of the bilateral hind limbs for about 45 min after injection. To experimentally manipulate the scratch efficacy in these histamine models, we compared histamine's behavioral and neuronal effects between mice with intact and clipped nails on the hind paws. As expected, the clipping of the hind limb nail increased the number of scratches after the histamine injection. In the brains of mice exhibiting scratching behaviors, we analyzed the expression of the c-fos gene (Fos) as a readout of an immediate activation of neurons during itch/scratch and dopamine receptors (Drd1 and Drd2) using multiplex single-molecule fluorescence in situ hybridization (RNAscope) in the NAc and surrounding structures. We performed a model-free analysis of gene expression in geometrically divided NAc subregions without assuming the conventional core-shell divisions. The results indicated that even within the NAc, multiple subregions responded differentially to various itch/scratch conditions. We also found different clusters with neurons showing similar or opposite changes in Fos expression and the correlation between scratch number and Fos expression in different itch/scratch conditions. These regional differences and clusters would provide a basis for the complex role of the NAc and surrounding structures in encoding the outcomes of scratching behavior and itchy sensations.
Subject(s)
Histamine , Mice, Inbred C57BL , Nucleus Accumbens , Pruritus , Animals , Pruritus/physiopathology , Pruritus/pathology , Male , Behavior, Animal , Proto-Oncogene Proteins c-fos/metabolism , Neurons/metabolism , MiceABSTRACT
Atopic dermatitis has a substantial impact on sleep, appearance, psychological well-being, and other qualities of life. The visual appearance of lichenification, cheilitis, hyperpigmentation, ichthyosis, and erythema can be socially stigmatizing, and treatment of these symptoms is challenging. In managing pruritus in patients, practitioners should assess and document pruritus through questionnaires at each routine visit. Initially, practitioners should advise patients to employ nonpharmaceutical treatments such as emollients with wet wraps, elimination of triggers, changing scratching habits, and psychological interventions. If these methods of treatment are not successful or if the disease presentation is severe, pharmacological therapies should be employed. This chapter describes the therapeutic ladder for pruritus in atopic dermatitis and discusses each treatment modality in further detail for practitioners to advise their patients.First-line topical pharmaceutical agents include topical glucocorticoids and topical calcineurin inhibitors. Second-line topical agents include coal tar, menthol, capsaicin, or doxepin. After the use of topical agents has been exhausted, primary systemic agents can be applied. These include sedating antihistamines, nonsedating antihistamines, oral glucocorticoids, or cyclosporine A. Finally, neuromodulating or immunomodulating agents can be attempted, including SSRI/SNRIs, TCAs, immunosuppressants, neural modulators, and opioid receptor modulators. Outside of pharmacological treatments, phototherapy has been shown to provide a dramatic improvement of pruritus in atopic dermatitis and can be used at any stage of treatment including as a first-line agent.
Subject(s)
Dermatitis, Atopic , Pruritus , Humans , Antipruritics/therapeutic use , Calcineurin Inhibitors/therapeutic use , Dermatitis, Atopic/therapy , Dermatitis, Atopic/complications , Glucocorticoids/therapeutic use , Histamine Antagonists/therapeutic use , Phototherapy/methods , Pruritus/therapy , Pruritus/etiology , Pruritus/physiopathology , Pruritus/drug therapyABSTRACT
One of the most common and significant symptoms for skin disorders is pruritus. Additionally, it serves as a significant catalyst for the exacerbation or reoccurrence of skin diseases. Pruritus seriously affects patients' physical and mental health, and even the quality of life. It brings a heavy burden to the patients, the families, even the whole society. The pathogenesis and regulation mechanisms for pruritus are complicated and have not yet been elucidated. Previous clinical studies have shown that itch worsens at night in scabies, chronic pruritus, atopic dermatitis, and psoriasis, suggesting that skin pruritus may change with circadian rhythm. Cortisol, melatonin, core temperature, cytokines, and prostaglandins are the main regulatory factors of the circadian rhythm of pruritus. Recent studies have shown that some CLOCK genes, such as BMAL1, CLOCK, PER, and CRY, play an important role in the regulation of the circadian rhythm of pruritus by regulating the Janus tyrosine kinase (JAK)-signal transducer and activator of transcription (STAT) and nuclear factor kappa-B (NF-κB) signaling pathways. However, the mechanisms for circadian clock genes in regulation of circadian rhythm of pruritus have not been fully elucidated. Further studies on the mechanism of circadian clock genes in the regulation of circadian rhythm of pruritus will lay a foundation for elucidating the regulatory mechanisms for pruritus, and also provide new ideas for the control of pruritus and the alleviation of skin diseases.
Subject(s)
Circadian Rhythm , Pruritus , Pruritus/physiopathology , Pruritus/etiology , Humans , Circadian Rhythm/physiology , CLOCK Proteins/genetics , CLOCK Proteins/metabolism , Signal Transduction , Melatonin/metabolism , ARNTL Transcription Factors/genetics , ARNTL Transcription Factors/metabolism , NF-kappa B/metabolism , Circadian Clocks/genetics , Circadian Clocks/physiologyABSTRACT
The phenomenon of contagious itch, observed in both humans and rodents, remains a topic of ongoing debate concerning its modulators and underlying pathways. This study delves into the relationship between contagious itch and familiar olfactory cues, a non-visual factor contributing to this intriguing behavior. Our findings showed that contagious itch in observer mice occurs during physical interaction with the cagemate itch-demonstrator but not with a stranger demonstrator or in a non-physical encounter condition. Notably, itch-experienced observer mice displayed an increased contagious itch behavior, highlighting the relevance of itch-associated memory in this phenomenon. Furthermore, anosmic observer mice, whether itch-naïve or itch-experienced, displayed no contagious itch behavior. These results demonstrate that the familiar olfactory cues, specifically cagemate body odors, are required for contagious itch behaviors in mice. In line with these behavioral findings, our study reveals increased activity in brain regions associated with olfaction, emotion, and memory during contagious itch, including the olfactory bulb, the amygdala, the hypothalamus, and the hippocampus, with this activity diminished in anosmic mice. In conclusion, our study unveils the critical role of familiar olfactory cues in driving contagious itch in mice, shedding light on the interplay between social factors, sensory perception, and memory in this phenomenon.
Subject(s)
Cues , Pruritus , Smell , Animals , Pruritus/physiopathology , Mice , Smell/physiology , Male , Behavior, Animal , Interpersonal Relations , Mice, Inbred C57BL , Odorants , Olfactory Bulb/physiopathology , Brain/physiopathologyABSTRACT
Itch is one of the most common clinical symptoms in patients with diseases of the skin, liver, or kidney, and it strongly triggers aversive emotion and scratching behavior. Previous studies have confirmed the role of the prelimbic cortex (Prl) and the nucleus accumbens core (NAcC), which are reward and motivation regulatory centers, in the regulation of itch. However, it is currently unclear whether the Prl-NAcC projection, an important pathway connecting these two brain regions, is involved in the regulation of itch and its associated negative emotions. In this study, rat models of acute neck and cheek itch were established by subcutaneous injection of 5-HT, compound 48/80, or chloroquine. Immunofluorescence experiments determined that the number of c-Fos-immunopositive neurons in the Prl increased during acute itch. Chemogenetic inhibition of Prl glutamatergic neurons or Prl-NAcC glutamatergic projections can inhibit both histaminergic and nonhistaminergic itch-scratching behaviors and rectify the itch-related conditioned place aversion (CPA) behavior associated with nonhistaminergic itch. The Prl-NAcC projection may play an important role in the positive regulation of itch-scratching behavior by mediating the negative emotions related to itch.
Subject(s)
Neural Pathways , Nucleus Accumbens , Pruritus , Rats, Sprague-Dawley , Animals , Pruritus/physiopathology , Nucleus Accumbens/physiology , Nucleus Accumbens/drug effects , Male , Rats , Neural Pathways/physiology , Neural Pathways/physiopathology , Disease Models, Animal , Neurons/physiology , Avoidance Learning/physiology , Behavior, Animal/physiology , Prefrontal Cortex/physiology , Prefrontal Cortex/metabolism , Proto-Oncogene Proteins c-fos/metabolismABSTRACT
INTRODUCTION: Pruritus, particularly in its chronic form, often imposes significant suffering and reductions in patients' quality of life. The pathophysiology of itch is varied depending on disease context, creating opportunities for unique drug development and multimodal therapy. AREAS COVERED: The purpose of this article is to provide an update of the literature regarding current and emerging therapeutics in itch. We review the multitudes of drug targets available and corresponding drugs that have shown efficacy in clinical trials, with a particular emphasis on phase 2 and 3 trials and beyond. Broadly, these targets include therapies directed against type 2 inflammation (i.e. Th2 cytokines, JAK/STAT, lipid mediators, T-cell mediators, and other enzymes and receptors) and neural receptors and targets (i.e. PARs, TRP channels, opioid receptors, MRGPRs, GABA receptors, and cannabinoid receptors). EXPERT OPINION: Therapeutics for itch are emerging at a remarkable pace, and we are entering an era with more and more specialized therapies. Increasingly, these treatments are able to relieve itch beyond their effect on inflammation by directly targeting the neurosensory system.
Subject(s)
Antipruritics , Drug Development , Pruritus , Quality of Life , Humans , Pruritus/drug therapy , Pruritus/physiopathology , Antipruritics/therapeutic use , Animals , Molecular Targeted Therapy , Chronic Disease , Inflammation/drug therapyABSTRACT
El prurito es el síntoma más frecuente asociado a enfermedades dermatológicas y sistémicas. Su diagnóstico es clínico, aunque en ocasiones será necesario realizar pruebas complementarias para identificar o confirmar el origen. La medicina traslacional ha permitido descubrir nuevos mediadores pruritógenos y nuevos receptores. Saber reconocer adecuadamente la principal vía por la que media el prurito en cada paciente será clave para el éxito terapéutico. La vía histaminérgica predomina en enfermedades como la urticaria o las reacciones a fármacos, mientras que la vía no histaminérgica predomina prácticamente en la mayoría de las otras dermatosis incluidas en esta revisión. La clasificación del prurito, las pruebas complementarias, la fisiopatología y los pruritógenos implicados, incluyendo citoquinas y otras moléculas, así como la sensibilización central al prurito que sufren estos pacientes formarán parte de este primer manuscrito sobre el prurito (AU)
Pruritus is the most common symptom of dermatologic and systemic diseases. The diagnosis of pruritus is clinical, although additional tests may be necessary to identify or confirm the cause. Translational medicine has led to the discovery of new mediators of itch, or pruritogens, as well as new receptors. Knowing how to properly recognize the main pathway that mediates itch in each patient is the key to successful treatment. Although the histaminergic pathway predominates in conditions like urticaria or drug-induced pruritus, it is the nonhistaminergic pathway that predominates in nearly all other skin diseases covered in this review. Part 1 of this 2-part review discusses the classification of pruritus, additional testing, the pathophysiology of itch and the pruritogens implicated (including cytokines and other molecules), and central sensitization to itch (AU)
Subject(s)
Humans , Pruritus/diagnosis , Pruritus/etiology , Pruritus/physiopathology , CytokinesABSTRACT
Pruritus is the most common symptom of dermatologic and systemic diseases. The diagnosis of pruritus is clinical, although additional tests may be necessary to identify or confirm the cause. Translational medicine has led to the discovery of new mediators of itch, or pruritogens, as well as new receptors. Knowing how to properly recognize the main pathway that mediates itch in each patient is the key to successful treatment. Although the histaminergic pathway predominates in conditions like urticaria or drug-induced pruritus, it is the nonhistaminergic pathway that predominates in nearly all other skin diseases covered in this review. Part 1 of this 2-part review discusses the classification of pruritus, additional testing, the pathophysiology of itch and the pruritogens implicated (including cytokines and other molecules), and central sensitization to itch (AU)
El prurito es el síntoma más frecuente asociado a enfermedades dermatológicas y sistémicas. Su diagnóstico es clínico, aunque en ocasiones será necesario realizar pruebas complementarias para identificar o confirmar el origen. La medicina traslacional ha permitido descubrir nuevos mediadores pruritógenos y nuevos receptores. Saber reconocer adecuadamente la principal vía por la que media el prurito en cada paciente será clave para el éxito terapéutico. La vía histaminérgica predomina en enfermedades como la urticaria o las reacciones a fármacos, mientras que la vía no histaminérgica predomina prácticamente en la mayoría de las otras dermatosis incluidas en esta revisión. La clasificación del prurito, las pruebas complementarias, la fisiopatología y los pruritógenos implicados, incluyendo citoquinas y otras moléculas, así como la sensibilización central al prurito que sufren estos pacientes formarán parte de este primer manuscrito sobre el prurito (AU)
Subject(s)
Humans , Pruritus/diagnosis , Pruritus/etiology , Pruritus/physiopathology , CytokinesABSTRACT
Pain and itch are distinct sensations arousing evasion and compulsive desire for scratching, respectively. It's unclear whether they could invoke different neural networks in the brain. Here, we use the type 1 herpes simplex virus H129 strain to trace the neural networks derived from two types of dorsal root ganglia (DRG) neurons: one kind of polymodal nociceptors containing galanin (Gal) and one type of pruriceptors expressing neurotensin (Nts). The DRG microinjection and immunosuppression were performed in transgenic mice to achieve a successful tracing from specific types of DRG neurons to the primary sensory cortex. About one-third of nuclei in the brain were labeled. More than half of them were differentially labeled in two networks. For the ascending pathways, the spinothalamic tract was absent in the network derived from Nts-expressing pruriceptors, and the two networks shared the spinobulbar projections but occupied different subnuclei. As to the motor systems, more neurons in the primary motor cortex and red nucleus of the somatic motor system participated in the Gal-containing nociceptor-derived network, while more neurons in the nucleus of the solitary tract (NST) and the dorsal motor nucleus of vagus nerve (DMX) of the emotional motor system was found in the Nts-expressing pruriceptor-derived network. Functional validation of differentially labeled nuclei by c-Fos test and chemogenetic inhibition suggested the red nucleus in facilitating the response to noxious heat and the NST/DMX in regulating the histamine-induced scratching. Thus, we reveal the organization of neural networks in a DRG neuron type-dependent manner for processing pain and itch.
Subject(s)
Galanin , Ganglia, Spinal , Nerve Net , Neurotensin , Nociceptors , Pain , Pruritus , Animals , Galanin/metabolism , Ganglia, Spinal/ultrastructure , Herpesvirus 1, Human , Mice , Mice, Transgenic , Nerve Net/ultrastructure , Neurotensin/metabolism , Nociceptors/metabolism , Pain/physiopathology , Pruritus/physiopathology , Solitary Nucleus/ultrastructureABSTRACT
Itch triggers scratching, a behavioural defence mechanism that aids in the removal of harmful irritants and parasites1. Chemical itch is triggered by many endogenous and exogenous cues, such as pro-inflammatory histamine, which is released during an allergic reaction1. Mechanical itch can be triggered by light sensations such as wool fibres or a crawling insect2. In contrast to chemical itch pathways, which have been extensively studied, the mechanisms that underlie the transduction of mechanical itch are largely unknown. Here we show that the mechanically activated ion channel PIEZO1 (ref. 3) is selectively expressed by itch-specific sensory neurons and is required for their mechanically activated currents. Loss of PIEZO1 function in peripheral neurons greatly reduces mechanically evoked scratching behaviours and both acute and chronic itch-evoked sensitization. Finally, mice expressing a gain-of-function Piezo1 allele4 exhibit enhanced mechanical itch behaviours. Our studies reveal the polymodal nature of itch sensory neurons and identify a role for PIEZO1 in the sensation of itch.
Subject(s)
Ion Channels , Pruritus , Alleles , Animals , Ion Channels/deficiency , Ion Channels/genetics , Ion Channels/metabolism , Mice , Pruritus/genetics , Pruritus/physiopathology , Sensation , Sensory Receptor Cells/metabolismABSTRACT
In perilous and stressful situations, the ability to suppress pain can be critical for survival. The rostral ventromedial medulla contains neurons that robustly inhibit nocioception at the level of the spinal cord through a top-down modulatory pathway. Although much is known about the role of the rostral ventromedial medulla in the inhibition of pain, the precise ability to directly manipulate pain-inhibitory neurons in the rostral ventromedial medulla has never been achieved. We now expose a cellular circuit that inhibits nocioception and itch in mice. Through a combination of molecular, tracing and behavioural approaches, we found that rostral ventromedial medulla neurons containing the kappa-opioid receptor inhibit itch and nocioception. With chemogenetic inhibition, we uncovered that these neurons are required for stress-induced analgesia. Using intersectional chemogenetic and pharmacological approaches, we determined that rostral ventromedial medulla kappa-opioid receptor neurons inhibit nocioception and itch through a descending circuit. Lastly, we identified a dynorphinergic pathway arising from the periaqueductal grey that modulates nociception within the rostral ventromedial medulla. These discoveries highlight a distinct population of rostral ventromedial medulla neurons capable of broadly and robustly inhibiting itch and nocioception.
Subject(s)
Medulla Oblongata , Neurons , Pain , Pruritus , Receptors, Opioid, kappa , Animals , Medulla Oblongata/cytology , Mice , Neurons/physiology , Pain/physiopathology , Pruritus/physiopathology , Receptors, Opioid, kappa/metabolismABSTRACT
The transient receptor potential (TRP) channel superfamily responds to various physical, chemical, and environmental stimuli including the detection of sensations both harmful and non-harmful. Among these sensations is pruritus, or itch. There are at least 27 different TRP channels and about six of them are involved in pruriception. The function of these six receptors is primarily seen in the skin and the dorsal root ganglia. Identification and biological insights provided by these receptors in pruriception is important for human health as mutations and activations of many of these channels cause discomfort and disease. This review will focus on involvement of TRP channels in pruriception that may render these channels as the targets of many antagonistic topical medications, which may help patients' better cope with the pruritus that results from various cutaneous and systemic diseases.
Subject(s)
Pruritus/metabolism , Pruritus/physiopathology , Sensory Receptor Cells/metabolism , Transient Receptor Potential Channels/metabolism , Animals , HumansABSTRACT
Itch is a complex symptom that is both common and burdensome in atopic dermatitis (AD). Yet, little is known about the longitudinal course of itch in AD. A prospective, dermatology practice-based study was performed of adults with AD (n = 463). Patients were assessed at baseline and approximately 6, 12, 18 and 24 months. Itch was assessed using Numeric Rating Scale (NRS) average and worst-itch scores, and frequency of itch in the past week. Repeated-measures regression models were constructed to examine itch over time. Overall, 31.5% and 22.5% had moderate (4-6) or severe (7-10) NRS average-itch scores; 27.4% and 36.4% had moderate (4-6) or severe (7-10) NRS worst-itch scores; 12.7% and 62.0% had itch from eczema 3-4 and ≥ 5 days in the past week; 27.4% and 45.1% reported sometimes and often/almost always having itch, respectively. Among patients with baseline moderate (4-6) or severe (7-10) NRS average-itch scores, 21.2% and 16.3% continued to have moderate or severe scores at ≥ 1 follow-up visits. In repeated-measures regression models, persistent NRS average-itch scores were associated with baseline NRS average-itch [adjusted ß (95% CI): 0.75 (0.68, 0.82)] and food allergy [- 0.45 (- 0.84, - 0.07)]. Persistent NRS worst-itch was associated with baseline worst-itch NRS [0.73 (0.66, 0.80)] and Medicaid insurance [1.06 (0.17, 1.94)]. AD patients had a heterogeneous longitudinal course with fluctuating and complex overlapping patterns of average- and worst-itch intensity, and frequency.
Subject(s)
Dermatitis, Atopic/physiopathology , Pruritus/physiopathology , Adolescent , Adult , Aged , Aged, 80 and over , Female , Humans , Longitudinal Studies , Male , Middle Aged , Prospective Studies , Quality of Life , Severity of Illness Index , Surveys and Questionnaires , Young AdultABSTRACT
Itch is an unpleasant somatic sensation with the desire to scratch, and it consists of sensory, affective, and motivational components. Acute itch serves as a critical protective mechanism because an itch-evoked scratching response will help to remove harmful substances invading the skin. Recently, exciting progress has been made in deciphering the mechanisms of itch at both the peripheral nervous system and the CNS levels. Key neuronal subtypes and circuits have been revealed for ascending transmission and the descending modulation of itch. In this review, we mainly summarize the current understanding of the central circuit mechanisms of itch in the brain.
Subject(s)
Brain/physiology , Neurons/physiology , Pruritus/physiopathology , Animals , Cell Communication , Central Nervous System , Humans , Motivation , Peripheral Nervous System , SensationABSTRACT
Histamine-dependent and -independent itch is conveyed by parallel peripheral neural pathways that express gastrin-releasing peptide (GRP) and neuromedin B (NMB), respectively, to the spinal cord of mice. B-type natriuretic peptide (BNP) has been proposed to transmit both types of itch via its receptor NPRA encoded by Npr1. However, BNP also binds to its cognate receptor, NPRC encoded by Npr3 with equal potency. Moreover, natriuretic peptides (NP) signal through the Gi-couped inhibitory cGMP pathway that is supposed to inhibit neuronal activity, raising the question of how BNP may transmit itch information. Here, we report that Npr3 expression in laminae I-II of the dorsal horn partially overlaps with NMB receptor (NMBR) that transmits histaminergic itch via Gq-couped PLCß-Ca2+ signaling pathway. Functional studies indicate that NPRC is required for itch evoked by histamine but not chloroquine (CQ), a nonhistaminergic pruritogen. Importantly, BNP significantly facilitates scratching behaviors mediated by NMB, but not GRP. Consistently, BNP evoked Ca2+ responses in NMBR/NPRC HEK 293 cells and NMBR/NPRC dorsal horn neurons. These results reveal a previously unknown mechanism by which BNP facilitates NMB-encoded itch through a novel NPRC-NMBR cross-signaling in mice. Our studies uncover distinct modes of action for neuropeptides in transmission and modulation of itch in mice.
An itch is a common sensation that makes us want to scratch. Most short-term itches are caused by histamine, a chemical that is released by immune cells following an infection or in response to an allergic reaction. Chronic itching, on the other hand, is not usually triggered by histamine, and is typically the result of neurological or skin disorders, such as atopic dermatitis. The sensation of itching is generated by signals that travel from the skin to nerve cells in the spinal cord. Studies in mice have shown that the neuropeptides responsible for delivering these signals differ depending on whether or not the itch involves histamine: GRPs (short for gastrin-releasing proteins) convey histamine-independent itches, while NMBs (short for neuromedin B) convey histamine-dependent itches. It has been proposed that another neuropeptide called BNP (short for B-type natriuretic peptide) is able to transmit both types of itch signals to the spinal cord. But it remains unclear how this signaling molecule is able to do this. To investigate, Meng, Liu, Liu, Liu et al. carried out a combination of behavioral, molecular and pharmacological experiments in mice and nerve cells cultured in a laboratory. The experiments showed that BNP alone cannot transmit the sensation of itching, but it can boost itching signals that are triggered by histamine. It is widely believed that BNP activates a receptor protein called NPRA. However, Meng et al. found that the BNP actually binds to another protein which alters the function of the receptor activated by NMBs. These findings suggest that BNP modulates rather than initiates histamine-dependent itching by enhancing the interaction between NMBs and their receptor. Understanding how itch signals travel from the skin to neurons in the spinal cord is crucial for designing new treatments for chronic itching. The work by Meng et al. suggests that treatments targeting NPRA, which was thought to be a key itch receptor, may not be effective against chronic itching, and that other drug targets need to be explored.
Subject(s)
Natriuretic Peptide, Brain/genetics , Neurokinin B/analogs & derivatives , Pruritus/genetics , Receptors, Atrial Natriuretic Factor/genetics , Signal Transduction , Animals , Ganglia, Spinal/metabolism , HEK293 Cells , Histamine/metabolism , Humans , Male , Mice , Mice, Inbred C57BL , Natriuretic Peptide, Brain/metabolism , Neurokinin B/genetics , Neurokinin B/metabolism , Pruritus/physiopathology , Receptors, Atrial Natriuretic Factor/metabolism , Spinal Cord/metabolismABSTRACT
Glial cells are non-neuronal cells in the nervous system that are electrically non-excitable and outnumber neurons in humans. Glial cells have attracted attention in recent years for their active involvement in the regulation of neuronal activity, suggesting their contribution to the pathogenesis and progression of neurological diseases. Studies have shown that astrocytes, a type of glial cell, are activated in the spinal cord in response to skin inflammation and contribute to the exacerbation of chronic itch. This review summarizes the current knowledge about the role of astrocytes and other glial cells in the modulation of itch processing and the mechanism of their activation under itch conditions.
Subject(s)
Astrocytes/metabolism , Neuroglia/metabolism , Pruritus/physiopathology , Animals , Chronic Disease , Humans , Inflammation/physiopathology , Neurons/metabolism , Spinal Cord/metabolismABSTRACT
In infants, pruritus is frequently considered as absent because they do not scratch themselves. Because pruritus could induce severe adverse effects in this vulnerable population, we aimed to review existing evidence on the ability of young infants to experience itch and on how to assess itch-related discomfort in this population. A literature review was performed (Pubmed, Google Scholar). Neurological itch pathways are well described. Skin development starts early during gestation. At 34 weeks of gestation, skin is almost complete while skin adaptations occur after birth. Newborn skin is neurologically functional, including the ability for young infants to feel pain. Similarities and interactions between pain and pruritus support the hypothesis that infants could feel pruritus. However, the existence of pruritus in infants has never been evidenced. Many itchy conditions can affect them, suggesting non-negligible prevalence of infant pruritus among which atopic dermatitis (AD) is the most studied disease. Studies reported a negative impact of AD on children and their families. There is no existing validated method to assess pruritus in infants, although they may feel pruritus and chronic pruritus can lead to serious adverse effects. To appropriately diagnose pruritus appears of great interest among young infants. Development of a method is required to this aim.
Subject(s)
Pruritus/pathology , Biomedical Research , Humans , Infant , Pain/complications , Pain/physiopathology , Pruritus/epidemiology , Pruritus/etiology , Pruritus/physiopathology , Skin/pathologyABSTRACT
The primary somatosensory cortex (S1) plays a critical role in processing multiple somatosensations, but the mechanism underlying the representation of different submodalities of somatosensation in S1 remains unclear. Using in vivo two-photon calcium imaging that simultaneously monitors hundreds of layer 2/3 pyramidal S1 neurons of awake male mice, we examined neuronal responses triggered by mechanical, thermal, or pruritic stimuli. We found that mechanical, thermal, and pruritic stimuli activated largely overlapping neuronal populations in the same somatotopic S1 subregion. Population decoding analysis revealed that the local neuronal population in S1 encoded sufficient information to distinguish different somatosensory submodalities. Although multimodal S1 neurons responding to multiple types of stimuli exhibited no spatial clustering, S1 neurons preferring mechanical and thermal stimuli tended to show local clustering. These findings demonstrated the coding scheme of different submodalities of somatosensation in S1, paving the way for a deeper understanding of the processing and integration of multimodal somatosensory information in the cortex.SIGNIFICANCE STATEMENT Cortical processing of somatosensory information is one of the most fundamental aspects in cognitive neuroscience. Previous studies mainly focused on mechanical sensory processing within the rodent whisking system, but mechanisms underlying the coding of multiple somatosensations remain largely unknown. In this study, we examined the representation of mechanical, thermal, and pruritic stimuli in S1 by in vivo two-photon calcium imaging of awake mice. We revealed a multiplexed representation for multiple somatosensory stimuli in S1 and demonstrated that the activity of a small population of S1 neurons is capable of decoding different somatosensory submodalities. Our results elucidate the coding mechanism for multiple somatosensations in S1 and provide new insights that improve the present understanding of how the brain processes multimodal sensory information.
