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Hereditary sensory and autonomic neuropathy

Hereditary sensory and autonomic neuropathy (HSAN) is a group of rare, inherited disorders characterized by progressive degeneration of the peripheral sensory and autonomic nerves, resulting in , autonomic dysfunction, and occasionally motor involvement. These conditions primarily affect small unmyelinated and thinly myelinated fibers responsible for , , and autonomic functions such as sweating and regulation. HSAN encompasses a clinically and genetically heterogeneous spectrum, with onset ranging from congenital to adulthood, and symptoms including numbness, chronic ulcers, insensitivity to , and autonomic disturbances like or anhidrosis. HSAN is classified into at least eight types (I–VIII), distinguished by mode of , age of onset, predominant features, and underlying genetic mutations, with further subtypes due to . Type I (HSN1), the most common form, follows an autosomal dominant pattern with onset typically in the second to fifth decade of life; it features prominent distal in the limbs, leading to foot ulcers, infections, and Charcot joints, with milder autonomic involvement such as sweating abnormalities, and is linked to mutations in genes like SPTLC1 on 9q22. Type II is autosomal recessive and congenital, causing profound loss of all sensory modalities from birth, often resulting in self-mutilation, , and recurrent fractures due to lack of perception. Type III, also known as or Riley-Day syndrome, is autosomal recessive and primarily affects individuals of Ashkenazi Jewish descent, presenting with severe autonomic crises, alacrima, and gastrointestinal dysmotility from infancy, caused by mutations in the IKBKAP gene on 9q31. Type IV (congenital insensitivity to pain with anhidrosis) is autosomal recessive, with neonatal onset marked by recurrent fevers from impaired sweating, episodic , and painless injuries leading to , attributed to NTRK1 gene mutations on 1q21-q22. Type V is similar to type IV but features insensitivity to and with only partial anhidrosis, and is associated with mutations in the NGF gene. Diagnosis of HSAN relies on clinical evaluation, family history, nerve conduction studies showing absent sensory responses, revealing reduced intraepidermal nerve fiber density, and to identify specific mutations. These disorders are collectively rare, with prevalence estimates varying by type—such as approximately 1 in 3,600 live births for type III in affected populations—but overall incidence is low worldwide, affecting both sexes equally. is supportive, focusing on wound care, pain control, autonomic symptom treatment, and , as no curative therapies exist.

Introduction

Definition and characteristics

Hereditary sensory and autonomic neuropathy (HSAN) refers to a heterogeneous group of rare inherited disorders that primarily affect the sensory and autonomic components of the , characterized by progressive degeneration of sensory and autonomic neurons. These conditions lead to profound , autonomic dysfunction, and secondary complications such as recurrent ulcers, infections, and tissue damage due to unnoticed injuries. HSAN is distinguished from other inherited neuropathies, such as Charcot-Marie-Tooth disease, by its predominant focus on sensory and autonomic deficits rather than motor involvement, although some overlap exists in certain subtypes. The core neuropathological features involve selective damage to small unmyelinated C-fibers, which transmit and sensations, and thinly myelinated A-delta fibers, with variable and often milder effects on larger myelinated fibers responsible for touch, , and . Autonomic involvement manifests in disruptions to functions like sweating, regulation, and gastrointestinal , contributing to the clinical heterogeneity across cases. Historically, these disorders were termed "hereditary sensory neuropathies" to emphasize , but the nomenclature shifted to HSAN in the late to encompass the significant autonomic features identified through advanced clinical and genetic studies. Currently, HSAN is classified into eight main types based on phenotypic, genetic, and differences, providing a framework for understanding their diversity without implying uniform progression or severity.

Epidemiology

Hereditary sensory and autonomic neuropathy (HSAN) is a group of rare disorders, with most types exhibiting a global of less than in 100,000 individuals. Type , the most common subtype, has an estimated of to 2 per 100,000 people, while rarer forms such as types 2, 4, and 8 show even lower frequencies, often with only several hundred cases documented worldwide. An exception is type 3 (), which has a of approximately in 3,600 to 3,700 live births specifically among Ashkenazi Jewish populations. Precise global incidence figures for HSAN are unavailable due to significant underdiagnosis and underreporting, as the condition is often misidentified or overlooked in clinical settings, particularly in regions with limited access to specialized neurological evaluation. Type 1 represents the predominant form among hereditary sensory neuropathies diagnosed in adults, comprising a substantial proportion of reported cases in this demographic. Ethnic and geographic variations are notable across subtypes. Type 3 occurs almost exclusively in individuals of Eastern European (Ashkenazi) Jewish descent due to a founder effect, with carrier rates around 1 in 30 to 36 in this group. In contrast, type 1 is reported worldwide, with clusters observed among those of European ancestry, though it lacks strong ethnic specificity. Types 2 and 4 through 8 are rarer and lack predominant ethnic biases, with case reports emerging from diverse backgrounds, including Middle Eastern, Asian (such as Japanese populations for types 4 and 5), and consanguineous families globally. No consistent sex bias is observed across HSAN types, affecting males and females equally. Age of onset varies by subtype, with type 1 typically manifesting in adulthood (second to fifth decade) and types 2 through 8 presenting congenitally or in early infancy.

Pathophysiology

Neuronal degeneration

The primary pathology in hereditary sensory and autonomic neuropathy (HSAN) involves progressive axonal atrophy and degeneration of neurons within the dorsal root ganglia, which initiates a distal dying-back process in sensory s. This degeneration typically begins at the distal ends of axons and progresses proximally, leading to a length-dependent of function. Studies of biopsies have demonstrated marked reduction in nerve fiber density, with endoneurial in advanced cases, underscoring the axonal nature of the damage. The degeneration predominantly affects small-diameter sensory fibers, including unmyelinated C-fibers and thinly myelinated A-delta fibers, which mediate , temperature sensation, and autonomic functions. Large myelinated fibers (A-alpha and A-beta), responsible for touch and , may be spared in early stages or variably involved, potentially resulting in proprioceptive deficits in some cases. Autonomic involvement includes degeneration of postganglionic sympathetic and parasympathetic fibers, manifesting as sudomotor dysfunction (e.g., anhidrosis) and vasomotor instability due to sparse innervation of sweat glands and blood vessels. Secondary changes arise from the sensory insensitivity and autonomic disruptions, including neurogenic inflammation that exacerbates tissue damage. Chronic lack of pain perception leads to unrecognized trauma, promoting and the development of Charcot joints in advanced stages, characterized by destruction and instability. These complications are particularly noted in joints like the ankles. Histological examinations reveal reduced intraepidermal nerve fiber density on punch biopsies, often below the fifth percentile for age-matched controls, confirming small-fiber loss. Sural nerve biopsies show axonal degeneration with minimal demyelination, and onion-bulb formations—remnants of proliferation—are rare, distinguishing HSAN from demyelinating neuropathies. Degeneration patterns vary by HSAN type, with some showing more profound early involvement of unmyelinated fibers.

Molecular pathways

Due to the clinical and of HSAN, molecular pathways differ across types. In HSAN type I, disruptions in metabolism, where defects in the rate-limiting step of lead to the accumulation of atypical deoxysphingolipids, interfere with mitochondrial function, stress responses, and axonal integrity, ultimately promoting neuronal toxicity and degeneration. In HSAN types IV and V, impairments in signaling, particularly involving (NGF) and its high-affinity receptor TrkA, compromise the survival, differentiation, and maintenance of sensory neurons during development and adulthood, resulting in reduced and apoptotic loss of nociceptive neurons. Additionally, in subtypes like HSAN IID, alterations in function, such as those affecting voltage-gated sodium channels (e.g., SCN9A), disrupt propagation and nociceptive signaling in peripheral sensory neurons, leading to insensitivity to pain and temperature. Autonomic-specific molecular disruptions in HSAN often stem from altered in neural crest-derived cells, which give rise to sympathetic neurons and their targets. These changes impair catecholamine biosynthesis pathways, including the regulation of enzymes like , resulting in deficient norepinephrine and epinephrine production and subsequent autonomic instability. Furthermore, defective signaling affects the innervation of sweat glands, involving disrupted neurotrophic support and cytoskeletal organization in postganglionic sympathetic fibers, which leads to anhidrosis and thermoregulatory failure. The progressive nature of HSAN involves the accumulation of misfolded proteins, which overwhelms cellular and triggers stress, exacerbating neuronal vulnerability. Impaired , mediated by disruptions in microtubule-based motor proteins and vesicular trafficking, hinders the delivery of essential cargoes such as and organelles to distal axons, fostering a dying-back pattern of chronic degeneration. Insights from animal models, including knockout mice with targeted disruptions in relevant pathways, reveal mechanisms of apoptosis through heightened caspase activation and reduced anti-apoptotic signaling, alongside autonomic failure manifested as sympathetic hypoinnervation and cardiovascular dysregulation. In contrast to acquired neuropathies, which typically arise from postnatal toxic, metabolic, or inflammatory insults targeting mature neurons, the inherited disruptions in congenital-onset HSAN types (e.g., II-V) often initiate during embryonic , leading to deficits in neuronal specification and connectivity; late-onset types like HSAN I, however, involve progressive postnatal degeneration rather than primary congenital damage. Newer types, such as HSAN VI (ATP13A2 mutations affecting lysosomal function) and HSAN VIII (PRDM12 mutations impacting epigenetic regulation of ), further highlight this diversity.

Classification

Type 1

Hereditary sensory and autonomic neuropathy type 1 (HSAN1) is the most common form of hereditary sensory neuropathy, characterized by its autosomal dominant and adult-onset presentation. It typically begins in the third to fifth decade of life, with initial symptoms manifesting as distal in the feet, often described as numbness, tingling, or sharp pains. Over years, the sensory impairment progresses slowly to involve the hands and, in advanced stages, more proximal limbs, leading to significant disability in many cases. The hallmark sensory features of HSAN1 involve a prominent and selective loss of and sensation due to degeneration of small unmyelinated fibers, while large-fiber functions such as touch and vibration sense are relatively preserved in the early stages. This predisposes individuals to recurrent foot ulcers, secondary infections, and Charcot arthropathy, often resulting in , bone fractures, and, in severe cases, amputations. Patients may also experience lancinating or burning pains in the affected areas, exacerbating the clinical burden. Autonomic involvement in HSAN1 is generally mild compared to other types, manifesting as distal , vasomotor instability, or subtle sweating abnormalities, with rare instances of more pronounced such as . Late in the disease course, mild distal motor weakness and may develop, contributing to foot deformities like . In certain subtypes, such as HSAN1E, can occur as an additional manifestation. HSAN1 shows a higher prevalence among adults evaluated for , estimated at approximately 2 per 1,000,000 individuals overall, and is primarily linked to mutations in genes such as SPTLC1.

Type 2

Hereditary sensory and autonomic neuropathy type 2 (HSAN2), also known as congenital sensory neuropathy, is an autosomal recessive disorder characterized by profound sensory deficits that manifest from birth or early infancy. The condition presents with severe loss of sensation to , , touch, , and across all modalities, affecting both small and large sensory fibers, and is typically non-progressive, though some cases show slow worsening over time. The hallmark sensory features include complete absence of pain and temperature perception in the limbs, leading to unrecognized injuries such as burns, cuts, and fractures that result in chronic ulcers, infections, , and self-mutilation behaviors like biting of the tongue, lips, or fingers starting as early as 4 months of age. This insensitivity to trauma also contributes to joint deformities, including Charcot joints, particularly in the hands and feet, due to repeated unnoticed damage. Autonomic involvement in HSAN2 is absent or minimal, with no significant disruptions to sweating, cardiovascular regulation, or orthostatic responses; occasional findings may include reduced lacrimation or mild gastroesophageal reflux, but these do not dominate the clinical picture. Additional manifestations encompass acral skeletal abnormalities such as shortened digits and recurrent painless fractures, alongside potential hypotonia, delayed motor milestones, and scoliosis in some individuals, though intellectual development remains unaffected and muscle strength is generally preserved without atrophy. Rare severe cases may involve respiratory complications like apnea or feeding difficulties. HSAN2 is subdivided into types A through D based on associated genes and varying degrees of limb involvement, with subtype A linked to the WNK1 gene and featuring more uniform distal sensory loss in all extremities.

Type 3

Hereditary sensory and autonomic neuropathy type 3, also known as (FD), is a rare autosomal recessive neurodegenerative disorder characterized by profound sensory and autonomic dysfunction, primarily affecting individuals of Ashkenazi Jewish descent with a prevalence of approximately 1 in 3,700 births in this population. The condition manifests from birth with lifelong symptoms, including feeding difficulties, poor muscle tone (), and recurrent , which contribute to high rates historically exceeding 50% in the first year, though supportive care has improved survival with about half of patients reaching adulthood. Progression involves delayed developmental milestones in childhood, followed by worsening balance issues, chronic lung and renal complications, and reduced , with average death occurring in the third decade despite advances in management. Sensory features in FD include variable loss of pain and temperature sensation, leading to insensitivity that increases injury risk, alongside reduced deep tendon reflexes and later vibratory sensory deficits. Corneal anesthesia is prominent, resulting in neurotrophic keratopathy and recurrent ulcers due to absent protective reflexes and tear production (alacrima). Intellectual function remains typically unimpaired, distinguishing it from more severe cognitive impacts in other neuropathies. Autonomic involvement is severe and hallmark, featuring absent fungiform papillae on the that impair and contribute to oral incoordination. Dysautonomic crises, occurring in up to 40% of patients with a cyclical pattern, involve intense , , , excessive sweating, and agitation, often triggered by emotional or infection. Additional autonomic disturbances include without compensatory , episodic supine , and temperature instability, and gastrointestinal dysmotility exacerbating feeding issues. Other manifestations encompass poor growth and , developmental delays, affecting 85% by age 10 and leading to , frequent fractures from poor bone quality, and progressive causing . Diagnostic clues include absent tear production upon emotional stimuli, lack of flare response to injection, and absence of deep reflexes, often confirmed alongside for mutations in the ELP1 (formerly IKBKAP) gene.

Type 4

Hereditary sensory and autonomic neuropathy type 4 (HSAN4), also known as with anhidrosis (CIPA), is a rare autosomal recessive characterized by profound insensitivity to and alongside absent sweating, leading to significant morbidity from unrecognized injuries and thermoregulatory failure. Onset is evident from birth or early infancy, often marked by recurrent episodes of unexplained fever due to anhidrosis, which can precipitate febrile seizures in hot environments. The condition is nonprogressive in its primary sensory deficits but leads to progressive orthopedic complications over time, such as deformities and chronic wounds from repeated trauma. Sensory features include complete insensitivity to and sensations, while touch, , and remain relatively preserved initially, allowing affected individuals to walk and perform daily activities without immediate motor impairment. This selective loss predisposes patients to self-mutilation behaviors, particularly in the oral region, where biting of the , , or fingers occurs without distress, resulting in scarring and potential auto-amputation. Autonomic involvement centers on severe anhidrosis affecting the and , though partial sweating may occur on the or , leading to recurrent and increased susceptibility to skin infections from poor heat dissipation. Mild dysfunction contributes to these thermoregulatory issues, but other autonomic functions, such as cardiovascular responses, are generally less affected. Other manifestations encompass frequent fractures due to unnoticed , development of Charcot joints from repetitive injury, and thickened with calluses as protective responses to chronic wounding. Intellectual function is typically preserved, though some individuals experience mild learning difficulties or hyperactivity. CIPA is caused by biallelic mutations in the NTRK1 gene. Globally, several hundred cases have been reported, with approximately 50% occurring in consanguineous families, highlighting its higher prevalence in populations with increased rates of related marriages.

Type 5

Hereditary sensory and autonomic neuropathy type 5 (HSAN5), also known as with partial anhidrosis, typically manifests in infancy with the development of distal ulcers due to unnoticed injuries from lack of perception. The condition progresses more slowly than HSAN type 4, with gradual worsening of sensory deficits leading to complications such as painless fractures, , and Charcot joints, often resulting in autoamputation of digits in affected individuals. Unlike the rapid and severe progression seen in other forms, HSAN5 patients experience a variable course, with poor and recurrent infections contributing to a prematurely aged appearance over time. The hallmark sensory feature of HSAN5 is profound insensitivity to , accompanied by impaired but variably preserved in certain areas, while touch, vibration, and remain largely intact. This selective loss primarily affects small myelinated fibers, leading to distal ulcers on the hands and feet, as well as self-mutilation behaviors such as biting of the , , or fingers due to the absence of . Autonomic involvement in HSAN5 is partial and milder compared to other types, characterized by patchy anhidrosis predominantly in the distal limbs, , and reduced tearing, but with fewer episodes of severe fever crises or hyperpyrexia. blotching and episodic increases in body temperature may occur, reflecting the incomplete disruption of function. Individuals with HSAN5 generally exhibit no , maintaining normal and mental status. HSAN5 is caused by homozygous mutations in the NGF gene, which encodes essential for survival. HSAN5 is exceedingly rare, with fewer documented cases than HSAN type 4, primarily reported in specific kindreds from regions such as , the , and isolated families worldwide. Its prevalence is estimated at less than 1 in 1,000,000.

Type 6

Hereditary sensory and autonomic neuropathy type 6 (HSAN6) is a rare autosomal recessive disorder characterized by a combination of progressive sensory loss, motor involvement, and mild autonomic dysfunction, primarily reported in consanguineous families. The condition manifests with neonatal that evolves into and joint contractures during childhood, leading to significant mobility impairment. Sensory deficits are prominent, featuring distal loss predominantly in the lower limbs, with variable impairment of pain and temperature sensation contributing to recurrent injuries and mutilations. Autonomic features are generally subtle, including mild gastrointestinal dysmotility such as constipation or delayed gastric emptying, without notable anhidrosis or prominent sweating abnormalities. involvement is evident through signs like , , and positive Babinski responses, reflecting degeneration alongside the peripheral neuropathy. Some individuals develop optic atrophy, potentially affecting vision, while respiratory complications may arise secondary to severe contractures or weakness in advanced stages. HSAN6 is caused by biallelic mutations in the DST gene on chromosome 6p12, encoding dystonin, a cytoskeletal linker protein essential for neuronal integrity. The disorder has been reported in multiple consanguineous and non-consanguineous families worldwide, with cases identified in diverse populations, highlighting its rarity but increased recognition through . Progression is relentless, with early sensory mutilations and often resulting in dependence by , underscoring the need for multidisciplinary focused on and supportive care.

Type 7

Hereditary sensory and autonomic neuropathy type 7 (HSAN7), also known as channelopathy-associated insensitivity to , is characterized by a selective and profound loss of perception present from birth, without significant involvement of other sensory modalities or autonomic functions. Onset occurs congenitally, with affected individuals demonstrating an inability to feel from infancy, leading to a lifelong risk of unrecognized injuries such as burns, fractures, and self-mutilation, particularly during early childhood when exploratory behaviors are common. Progression is non-degenerative in terms of neuropathy, but cumulative damage from repeated trauma can result in secondary complications like deformities or wounds over time, though motor remains intact and intellect is normal. The primary sensory deficit in HSAN7 is a complete or near-complete insensitivity to nociceptive stimuli, while other sensations such as touch, , , and are preserved, allowing for normal coordination and daily activities aside from avoidance. Temperature may be partially affected due to the role of nociceptors, but patients can typically detect extremes through non-noxious pathways. This selective impairment arises from biallelic loss-of-function mutations in the SCN9A gene, which encodes the Nav1.7 voltage-gated essential for propagation in pain-sensing neurons. Autonomic functions are notably spared in HSAN7, with normal sweating responses, cardiovascular regulation, and gastrointestinal motility, distinguishing it from other forms of congenital insensitivity that include anhidrosis or . Patients do not experience the fever or overheating risks seen in anhidrosis-associated types, though unnoticed injuries can lead to secondary infections and unexplained fevers. Other manifestations include a predisposition to self-injurious behaviors, such as biting the or fingers, and potential corneal abrasions from lack of feedback during eye rubbing, but there is no primary tendency for skin ulcers or bone abnormalities as initial features. In contrast to other insensitivities to pain, such as HSAN type 4 (with anhidrosis) or type 5 (with partial anhidrosis and self-mutilation), HSAN7 lacks autonomic deficits and features preserved non-painful sensations, emphasizing its channelopathy-specific profile without widespread or intellectual impairment.

Type 8

Hereditary sensory and autonomic neuropathy type 8 (HSAN8) is a rare autosomal recessive disorder characterized by , with onset evident in the first months of life through painless injuries and lack of response to noxious stimuli. The remains stable without progression over time, distinguishing it from other HSAN types that may involve worsening neuropathy, though secondary complications such as recurrent ulcers and infections can accumulate due to repeated trauma. Reported cases, numbering fewer than 20 families worldwide, often arise in consanguineous pedigrees, reflecting the homozygous nature of the underlying mutations. Sensory deficits in HSAN8 primarily affect small-fiber modalities, resulting in profound loss of pain and temperature sensation in the distal limbs, while large-fiber functions such as touch, vibration, , and olfaction are preserved. This selective impairment leads to characteristic self-mutilation behaviors, including biting of the , , and fingers, as well as painless burns and injuries that progress to chronic ulcers, particularly on the hands and feet. The absence of corneal reflexes further contributes to corneal scarring and potential vision issues from unchecked trauma. Autonomic involvement in HSAN8 is mild and variable, often limited to hypohidrosis or anhidrosis, with reduced sweat and tear production but without severe . Motor function and cognitive development remain normal, allowing affected individuals to achieve typical milestones despite the sensory challenges. HSAN8 results from biallelic mutations in the PRDM12 gene, as detailed in the genetics section.

Genetics

Inheritance patterns

Hereditary sensory and autonomic neuropathy (HSAN) encompasses a group of disorders with distinct patterns, primarily autosomal dominant for type 1 and autosomal recessive for types 2–6 and 8, while type 7 follows an autosomal dominant pattern. Type 1 HSAN follows an autosomal dominant mode of transmission, characterized by incomplete , where not all carriers develop symptoms. In contrast, types 2–6 and 8 exhibit autosomal recessive inheritance with complete , meaning affected individuals are homozygous or compound heterozygous for pathogenic variants, and carriers remain . Type 7 is autosomal dominant with complete penetrance. Variable expressivity is prominent in HSAN type 1, often manifesting as age-dependent onset typically in the second to fifth decade of life, leading to differences in symptom severity and progression among affected family members. For type 3 HSAN (), a notable exists in Ashkenazi Jewish populations due to a common homozygous in the IKBKAP , contributing to its higher prevalence in this group (incidence approximately 1 in 3,600 live births). No established X-linked or mitochondrial inheritance patterns have been identified for HSAN, though mutations can occur in autosomal dominant forms like type 1, explaining sporadic cases without family history. Consanguinity plays a significant role in the recessive forms (types 2–6 and 8), particularly increasing their incidence in isolated or endogamous populations, as seen in up to 50% of reported type 4 cases. analysis and detailed family history are crucial for diagnosing HSAN, as they help distinguish modes and guide for relatives, especially in autosomal recessive types where unaffected parents may be carriers.

Associated genes

Hereditary sensory and autonomic neuropathy (HSAN) encompasses a group of genetically heterogeneous disorders, with each type primarily linked to mutations in distinct genes that disrupt sensory and autonomic neuron function. Locus heterogeneity exists within several types, where multiple genes can cause overlapping phenotypes, and emerging variants continue to refine classifications. Type 1 is most commonly associated with mutations in SPTLC1, which encodes the serine palmitoyltransferase long-chain base subunit 1, a key enzyme in sphingolipid biosynthesis; missense mutations lead to gain-of-function effects, resulting in the accumulation of neurotoxic deoxysphingolipids that impair axonal integrity. Additional genes include SPTLC2, encoding another subunit of the same enzyme complex and causing similar biochemical disruptions in HSAN1C; ATL1 and ATL3, which encode atlastin GTPases involved in endoplasmic reticulum shaping and fusion, with mutations affecting neuronal membrane dynamics; and DNMT1, which encodes DNA methyltransferase 1 responsible for epigenetic regulation via DNA methylation, where variants cause HSAN1E characterized by sensory loss alongside dementia and other features. Type 2 involves several genes reflecting its recessive inheritance and early-onset sensory loss. WNK1 mutations affect the HSN2-specific isoform, a that regulates development and in sensory neurons. FAM134B (also known as RETREG1) encodes an autophagy receptor crucial for reticulophagy and turnover, with biallelic loss-of-function variants leading to neuronal accumulation of damaged organelles. KIF1A codes for a family member essential for of synaptic vesicles and organelles, where pathogenic variants disrupt trafficking. SCN9A mutations, encoding the voltage-gated Nav1.7, are linked to this type through altered channel function, though typically gain-of-function variants are more common in disorders, with loss-of-function contributing to insensitivity in some cases. Type 3, also known as , is caused by in IKBKAP (also called ELP1), which encodes a protein in the elongator complex essential for transcriptional elongation and mRNA processing; a common intronic splicing (c.2204+6T>C) reduces functional IKAP protein levels, particularly in neuronal tissues, leading to developmental defects in sensory and autonomic ganglia. Type 4 arises from biallelic in NTRK1, encoding the TrkA that mediates (NGF) signaling critical for the survival, differentiation, and maintenance of nociceptive sensory neurons; loss-of-function variants abolish NGF-TrkA pathway activation, resulting in absent pain perception and anhidrosis. Type 5 is linked to mutations in NGF (NGFB), which encodes beta, a vital for development and survival; homozygous missense mutations impair ligand binding to receptors, causing selective loss of and sensation with preserved other modalities. The NGFR gene, encoding the p75 receptor that modulates NGF signaling, has been proposed as a candidate but lacks confirmed pathogenic variants in reported cases. Type 6 is associated with mutations in DST, encoding dystonin, a cytoplasmic adaptor protein that links to and intermediate filaments, facilitating intracellular trafficking and neuronal stability; biallelic variants disrupt these interactions, leading to severe early-onset sensory and autonomic failure. Type 7 results from loss-of-function mutations in SCN11A, which encodes the Nav1.9 subunit expressed in nociceptors; these variants abolish channel activity, preventing propagation and causing with mild autonomic dysfunction such as . Type 8 involves biallelic mutations in PRDM12, a PR/SET domain-containing that specifies identity during embryogenesis by regulating gene expression in pain-sensing pathways; pathogenic variants lead to loss of function, manifesting as insensitivity to and with self-mutilation.

Diagnosis

Clinical assessment

Clinical assessment of hereditary sensory and autonomic neuropathy (HSAN) begins with a detailed history to identify patterns suggestive of this group of inherited disorders, characterized by predominant sensory and autonomic dysfunction. is crucial, as many HSAN subtypes follow autosomal dominant , such as type 1, while others like types 2, 3, and 4 are autosomal recessive; consanguinity or affected siblings may point to recessive forms. Age of onset varies widely, from congenital in types 3 and 4 to or adulthood in type 1, helping narrow the subtype. patterns typically involve distal extremities, starting with numbness or insensitivity to and , progressing proximally in a length-dependent manner. Autonomic symptoms, such as anhidrosis leading to or episodic , are elicited through queries about sweating abnormalities, orthostatic , or gastrointestinal issues. History of self-injury incidents, including painless burns, fractures, or mutilations (e.g., in children), is a hallmark, particularly in early-onset types like 2 and 4. Physical examination focuses on confirming sensory and autonomic involvement while assessing for secondary complications. Sensory testing includes pinprick for pain perception and temperature discrimination using warm/cold objects, often revealing profound distal deficits in small-fiber modalities across HSAN subtypes. and position may be impaired in large-fiber predominant cases, such as type 1. Reflex assessment typically shows reduced or absent deep tendon reflexes, especially ankle jerks, due to associated axonal involvement. Autonomic signs are evaluated through orthostatic to detect and to light or , which may be sluggish in types with prominent autonomic features like type 3. Inspection of extremities is essential, revealing chronic ulcers, calluses, mutilations, or Charcot joints from unrecognized trauma, particularly on feet and hands. Red flags include a strikingly negative sensory examination with relatively preserved motor function, distinguishing HSAN from motor-predominant neuropathies like Charcot-Marie-Tooth disease. In suspected type 3 (Riley-Day syndrome), an Ashkenazi Jewish ethnic background raises suspicion for this recessive form. clues involve excluding acquired causes, such as (via absence of or history) or (no endemic exposure or skin lesions). A multidisciplinary approach is recommended early, involving neurologists for comprehensive neuropathy evaluation and geneticists for pedigree analysis and counseling, to facilitate timely subtype classification. For instance, dysautonomic crises may briefly suggest type 3 during history review.

Confirmatory tests

Confirmatory tests for hereditary sensory and autonomic neuropathy (HSAN) involve objective laboratory and physiological assessments to verify the and subtype the condition, distinguishing it from acquired neuropathies. Electrophysiological studies are a , typically revealing absent or severely reduced action potentials (SNAPs) across HSAN types, while motor nerve conduction velocities remain normal or only mildly reduced in early stages. Quantitative sensory testing complements this by demonstrating elevated thresholds for , , and vibratory stimuli, confirming small-fiber involvement. In HSAN type 1, for instance, SNAPs are universally absent in the lower extremities, correlating with disease severity. Skin biopsy provides direct evidence of small-fiber pathology, with punch biopsies from the distal leg showing reduced intraepidermal nerve fiber density (IENFD), often below 5 fibers/mm, indicative of axonal loss. Electron microscopy of sural nerve biopsies further reveals decreased unmyelinated C-fibers and small myelinated Aδ-fibers, particularly in types II and IV, where unmyelinated fiber absence is pronounced. In HSAN type 1, biopsies demonstrate complete denervation of the epidermis at distal sites, with partial preservation proximally. These findings have high specificity (95-97%) for small-fiber neuropathies when IENFD falls below the fifth percentile of normative values. Autonomic testing quantifies dysfunction in sudomotor, cardiovascular, and other pathways. The quantitative sudomotor axon reflex test (QSART) assesses postganglionic fibers, often showing absent or reduced sweat output leading to anhidrosis, a hallmark in type IV. Tilt-table testing evaluates without compensatory , prevalent in type III (Riley-Day syndrome). Thermoregulatory sweat tests map anhidrotic areas, confirming patchy or global sweating deficits, while the Composite Autonomic Scoring Scale (CASS) integrates results for overall severity, with mild scores (e.g., 1-2) common in early HSAN. These tests achieve high sensitivity (up to 90%) for autonomic involvement. Genetic testing is definitive for subtype , employing targeted next-generation sequencing panels that analyze over 20 genes associated with HSAN, such as SPTLC1 for type 1, IKBKAP for type III, and NTRK1 for type IV. Biallelic pathogenic variants confirm the diagnosis in most cases, with whole-exome sequencing reserved for novel or unresolved variants; for example, founder mutations in IKBKAP are identifiable in Ashkenazi Jewish populations with type III. Panels like those from or detect single nucleotide variants and copy number changes with high accuracy, guiding familial risk assessment. Imaging, primarily (MRI), plays a supportive role by excluding involvement or complications like infections, but it is not primary for peripheral HSAN confirmation, as nerve enlargement is atypical. In select subtypes, MRI may reveal , but findings are nonspecific.

Management

Supportive strategies

Supportive strategies for hereditary sensory and autonomic neuropathy (HSAN) focus on symptom , injury prevention, and improving through non-curative interventions. These approaches are tailored to the predominant and autonomic dysfunction across HSAN types, emphasizing multidisciplinary care to address complications such as ulcers, infections, and deformities. Wound and ulcer care is essential due to the profound sensory deficits that increase the risk of unnoticed injuries, particularly in the . Patients are advised to perform daily foot and limb inspections to identify cuts, blisters, or pressure sores early, following protocols similar to those for care, including cleaning wounds, applying protective dressings, and using antiseptic treatments to prevent infections like . Orthopedic footwear, custom , and braces help redistribute pressure and support joint stability, while and antibiotics are employed for established s or infections. Education on injury avoidance, such as wearing protective gloves during activities involving heat or , is provided to patients and families to minimize trauma. In HSAN type IV, for instance, additional measures like tooth filing or prevent self-mutilation-related oral wounds. Pain and sensory management addresses that may occur despite overall insensitivity, particularly in HSAN type I where shooting pains affect up to 80% of patients. Medications such as , , , or amitriptyline are used to alleviate these symptoms, often in combination for better efficacy. Protective devices, including padded gloves, helmets, and mobility aids, are recommended to safeguard against inadvertent injuries from falls or impacts. Although primary precludes typical pain sensation, these interventions focus on secondary discomfort and long-term protection. Autonomic support targets dysregulations like , anhidrosis, and gastrointestinal issues, varying by HSAN type. For orthostasis in HSAN type III, increased hydration, salt intake, elastic stockings, and medications such as (0.1 mg daily) or (0.05-0.1 mg/kg) help maintain stability. Anhidrosis in types IV and V requires aids, including cooling vests or air-conditioned environments, to prevent ; antipyretics like acetaminophen are used for fever management in type IV. Antiemetics and prokinetics manage vomiting or crises in type III, while fundoplication with tubes addresses and feeding difficulties across types. A multidisciplinary team, including neurologists, physical and occupational therapists, podiatrists, orthopedists, dentists, and nutritionists, coordinates care to manage deformities, self-mutilation, and growth issues. Physical and occupational therapy improves mobility, strengthens muscles, and prevents contractures through exercises and splinting. Dental interventions, such as protective mouth guards or behavioral modifications, reduce self-injurious biting in types , , and . Nutritional support via or supplements addresses growth delays and malnutrition risks from . Lifestyle modifications include referral to for families to discuss inheritance risks and reproductive options, alongside comprehensive education on and responses. Patients are encouraged to avoid high-risk activities, such as sports or extreme temperatures, and to maintain regular follow-ups at specialized centers for ongoing surveillance and adaptation of care plans.

Emerging therapies

Emerging therapies for hereditary sensory and autonomic neuropathy (HSAN) primarily target the underlying genetic defects and pathophysiological mechanisms, with a focus on disease-modifying interventions rather than symptomatic relief. Research has advanced particularly for HSAN type 3 (), where mutations in the IKBKAP cause aberrant splicing of 20, leading to reduced ELP1 protein levels essential for neuronal function. Antisense oligonucleotides () designed to correct this splicing defect have shown promise in preclinical models by increasing full-length IKBKAP transcripts and ELP1 protein expression in patient-derived cells and transgenic mice. An ongoing N-of-1 as of 2025 evaluates the safety and efficacy of of such an , aiming to boost ELP1 levels and potentially halt disease progression. Complementary approaches include small-molecule splicing modulators like kinetin derivatives, which enhance IKBKAP splicing in preclinical studies, and their combination with ASOs or intravitreal vectors for broader delivery. For HSAN type 1, caused by gain-of-function mutations in SPTLC1 that elevate neurotoxic deoxysphingolipids, substrate reduction therapies aim to mitigate lipid accumulation. Preclinical evidence supports the use of L-serine supplementation to compete with the mutant enzyme's aberrant substrate preference, reducing toxic lipid levels in patient fibroblasts and improving survival . Clinical trials of oral L-serine have demonstrated tolerability and preliminary stabilization of neuropathy scores in small cohorts, though larger studies are needed to confirm efficacy. Direct SPTLC1 inhibitors remain in early , with models showing potential to suppress pathogenic lipid synthesis without broadly disrupting . In HSAN types 4 and 5, involving loss-of-function mutations in NTRK1 (encoding the NGF receptor TrkA) and NGF (encoding nerve growth factor beta), respectively, therapies seek to restore NGF-TrkA signaling for nociceptor development and survival. NGF agonists, such as recombinant NGF or small-molecule TrkA activators, have demonstrated neuroprotective effects in preclinical rodent models of NGF deficiency, promoting sensory axon innervation and pain sensitivity. These approaches reference the targeted genes like NTRK1 outlined in genetics sections, but no human trials specific to HSAN types 4 or 5 are active as of 2025. For HSAN type 7, resulting from loss-of-function SCN9A mutations impairing NaV1.7 sodium channels in nociceptors, CRISPR/Cas9-based gene editing holds theoretical promise for correcting variants in patient-derived cells, though applications remain preclinical without ongoing trials. Broader neuroprotective strategies explore agents to enhance axonal regeneration across HSAN subtypes. like (BDNF) have shown axon outgrowth promotion in injured sensory neurons , potentially countering degenerative loss. (HDAC) inhibitors, such as those targeting HDAC6, facilitate microtubule acetylation and growth cone dynamics, improving regeneration in models and preserving function in peripheral neuropathies. Preclinical data indicate HDAC inhibitors enhance sensory axon regrowth post-injury, but HSAN-specific trials are absent. Induced pluripotent stem cells (iPSCs) derived from HSAN patients enable disease modeling, revealing subtype-specific neuronal deficits like impaired differentiation in SPTLC1 mutants, and pave the way for autologous replacement therapies to repopulate sensory neurons. As of November 2025, clinical trials are limited, with phase I/II studies ongoing solely for HSAN type 3 therapies; no approved disease-modifying treatments exist for other HSAN types, emphasizing the need for expanded research into gene- and cell-based interventions.

Prognosis

Long-term outcomes

Hereditary sensory and autonomic neuropathy (HSAN) encompasses a group of disorders with variable long-term outcomes, often characterized by reduced in certain subtypes due to recurrent infections and complications such as amputations, particularly in types 1, 2, and 4. In HSAN type 1, the condition is slowly progressive, leading to significant by the fifth or sixth decade of life, though remains normal with appropriate of complications. For types 2 and 8, the disease tends to stabilize after early onset, but patients remain highly injury-prone throughout life, resulting in chronic morbidity without substantially shortening lifespan. HSAN type 6 exhibits variable severity and progression; in cases with significant motor involvement, use may be necessitated by childhood or adolescence due to sensory and motor deficits. In contrast, HSAN type 3 () has seen marked improvements, with current data indicating a 50% probability of survival to age 40, compared to historical rates where median survival was under 20 years. As of 2025, promising disease-modifying therapies targeting the ELP1 splicing defect are in development, potentially further improving survival and . Quality of life in HSAN is profoundly affected by high morbidity from recurrent ulcers and injuries, with a significant of amputations—particularly in type 1, where lower limb amputations occur frequently due to untreated foot ulcers. The sensory insensitivity contributes to psychological burdens, including anxiety over unrecognized injuries and from mobility limitations. Across subtypes, autonomic disturbances exacerbate daily challenges, such as temperature dysregulation and orthostatic issues, further diminishing independence. Advances in supportive , including prophylactic measures against infections, have improved overall , with early intervention correlating to better functional outcomes and extended survival, especially in type 3 where median lifespan now exceeds 40 years in managed cases. Factors such as timely and adherence to multidisciplinary plans—encompassing and orthopedic support—substantially mitigate progression and enhance across HSAN variants.

Complications

One of the primary complications arising from the sensory deficits in hereditary sensory and autonomic neuropathy (HSAN) involves chronic distal wounds and ulcers, particularly in types 1, 2, 4, 5, and 8, which often go unnoticed due to impaired pain perception. These wounds frequently become , leading to severe outcomes such as , a that can necessitate if untreated. Orthopedic issues are also prevalent, including Charcot arthropathy—a progressive joint destruction from repetitive trauma—and painless fractures resulting from unrecognized injuries, commonly observed in HSAN types 4 through 6. In HSAN type 3, develops in over 90% of affected individuals due to autonomic and sensory imbalances affecting spinal growth. Autonomic dysfunction contributes to crises in HSAN type 3, characterized by severe episodes that can cause and , alongside recurrent from and poor oral coordination. In anhidrotic forms such as types 4 and 5, impaired sweating leads to episodes of or heatstroke, especially in warm environments, due to ineffective . Additional complications include renal failure associated with amyloid deposition from chronic wound infections in certain subtypes like HSAN type 1E, as well as an elevated risk of developing from persistent ulcers in types such as HSAN 2A. Psychological effects, including anxiety related to frequent injuries and , further compound the burden, often stemming from the unpredictable nature of . Regular monitoring of skin integrity, joint health, and autonomic function plays a crucial role in early detection and prevention of these complications, thereby improving overall management as outlined in supportive care strategies.