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Dystrophy

Dystrophy is a medical referring to the process and consequences of hereditary progressive degeneration affecting specific cells in one or more tissues that initially function normally, leading to abnormal , weakening, or of those tissues. This condition arises from genetic abnormalities that impair nutrition or maintenance of the affected tissues, distinguishing it from acquired degenerations or congenital malformations present at birth. The encompasses a diverse group of inherited disorders, with symptoms typically emerging later in life and progressing over time. The most prominent category of dystrophies is , a collection of over 30 genetic diseases that primarily target skeletal muscles, causing progressive weakness, loss of muscle mass, and eventual disability. These disorders, such as (the most common and severe form, affecting about 1 in 3,500 to 5,000 male births) and , result from mutations in genes responsible for muscle protein production, like . Other significant types include corneal dystrophies, which involve bilateral, inherited abnormalities of the cornea leading to opacity, vision loss, and potential need for transplantation; examples are Fuchs endothelial dystrophy and lattice dystrophy. Additionally, retinal dystrophies affect the light-sensitive cells of the , resulting in progressive vision impairment; cone-rod dystrophy, for instance, leads to , night vision problems, and eventual legal blindness in many cases. Less common variants impact other structures, such as in nail dystrophy or bones in asphyxiating thoracic dystrophy, highlighting the term's broad application across organ systems. Diagnosis often involves , imaging, and , while management focuses on symptom relief, , and gene therapies to slow progression, including FDA-approved treatments like Elevidys for (as of 2025).

Overview

Definition and Etymology

The term "dystrophy" originates from the Greek roots dys- (meaning bad, abnormal, or faulty) and trophē (meaning nourishment), literally denoting defective or inadequate of s. This etymological foundation reflects the early understanding of the condition as a of sustenance, and the word entered medical via Modern Latin dystrophia in 1858. The term gained prominence in the late when German neurologist Wilhelm Erb coined Dystrophia muscularis progressiva in to describe progressive degeneration of muscle tissue, marking its initial application to specific pathological states. Subsequently, "dystrophy" was generalized beyond muscles to encompass similar processes in other organs and tissues, evolving from a descriptor of nutritional deficits to a broader category of degenerative disorders. Medically, dystrophy is defined as a degeneration or abnormal development of or organs, leading to structural and functional impairment arising from defective cellular nourishment. At its core, the concept implies an inherent, often irreversible breakdown due to underlying flaws in metabolic or nutritional processes at the cellular level. This distinguishes it from , which refers to reversible shrinkage typically caused by disuse, , or temporary nutritional deficiency, without the pathological progression inherent to dystrophy.

General Characteristics

Dystrophies encompass a diverse group of disorders characterized by the progressive degeneration of specific s or organs, where initially normal structures undergo hereditary progressive changes leading to structural and functional impairment. This degeneration typically involves the abnormal accumulation of proteins or other materials within cells, resulting in cellular dysfunction and eventual replacement by fibrous or . While the precise mechanisms vary, dystrophies generally manifest as noninflammatory processes that disrupt normal architecture without primary involvement of neural or vascular systems. Common clinical features across dystrophies include progressive weakness or loss of function in the affected tissue, accompanied by (atrophy) and eventual , where functional cells are supplanted by non-contractile . Pathological hallmarks often include accumulation of abnormal materials, cellular dysfunction, and in certain types, abnormal protein aggregates, increased cellular , and secondary , culminating in organ-level dysfunction; for instance, in muscle-involved cases, this can extend to multi-system effects such as cardiac or respiratory complications. These shared traits underscore the degenerative nature of dystrophies, distinguishing them from acute inflammatory or traumatic conditions. The age of onset for dystrophies varies widely, ranging from congenital forms evident at birth to childhood or adult-onset presentations, with hereditary factors predominating in most cases, though acquired influences can contribute. Inheritance patterns commonly follow autosomal recessive, autosomal dominant, or X-linked modes, influencing the variability in expression. Epidemiologically, dystrophies affect multiple body systems depending on the tissue targeted, and many forms are rare, with global often below 1 in 10,000 individuals, though rates differ by type and population.

Etiology

Genetic Factors

Dystrophies are hereditary disorders caused by genetic abnormalities that impair the nutrition or maintenance of affected tissues. While mutations can occur, they are relatively rare, typically representing less than one-third of instances in specific subtypes like . Muscular dystrophies serve as primary exemplars of these genetic mechanisms. Inheritance patterns in dystrophies vary, encompassing autosomal dominant, autosomal recessive, and X-linked recessive modes. In autosomal dominant forms, a single mutated from one parent suffices to cause the condition, as seen in myotonic dystrophy type 1. Autosomal recessive inheritance requires mutated from both parents, exemplified by congenital muscular dystrophies involving deficiencies. X-linked recessive patterns predominantly affect males, who inherit the mutation from carrier mothers; a classic case is due to mutations in the gene on the . At the molecular level, dystrophies often arise from in genes encoding structural proteins essential for , particularly in muscle and epithelial cells. These disrupt protein function, leading to impaired stability and progressive degeneration; for instance, compromise the dystrophin-glycoprotein complex, weakening muscle fiber attachment to the , while gene variants, such as in LAMA2, result in defective assembly and severe early-onset . A notable example is type 1, caused by trinucleotide repeat expansions of CTG in the 3' of the DMPK on , following an autosomal dominant pattern. Normal alleles contain fewer than 35 CTG repeats, but pathogenic expansions exceed 50, leading to toxic accumulation that sequesters RNA-binding proteins and disrupts cellular processes like splicing. These expansions are unstable and can increase across generations, a phenomenon known as .

Acquired Factors

Although dystrophies are primarily genetic, acquired factors can exacerbate progression or cause secondary changes resembling dystrophic degeneration in affected tissues, particularly in muscular and ocular forms. These modifiable environmental, nutritional, or disease-related elements may interact with underlying genetic defects to accelerate tissue breakdown and impair function. Nutritional deficiencies, such as protein-energy , can worsen muscle wasting and weakness in individuals with genetic dystrophies by further compromising tissue maintenance and promoting . Historical reports from periods of , including post-World War II, described severe undernutrition leading to , , and that compounded existing vulnerabilities. Environmental exposures, including radiation and certain chemicals, may induce additional damage in genetically susceptible tissues. For example, from therapeutic sources can lead to corneal decompensation and opacity in patients with preexisting corneal dystrophies, with doses exceeding 40 increasing the risk of complications like endothelial cell loss. Chronic exposure to toxins like may contribute to and muscle decline in those with muscular dystrophies. Disease-associated factors, such as chronic infections and autoimmune conditions, can heighten and immune-mediated damage, accelerating degeneration in dystrophic tissues. For instance, recurrent infections may promote in muscular dystrophies, while autoimmune disorders can co-occur and exacerbate remodeling in conditions like myotonic dystrophy type 2. In iatrogenic cases, long-term use can induce that mimics or compounds symptoms, affecting type II muscle fibers and causing proximal weakness with prolonged high doses (e.g., ≥40 mg/day). These acquired factors often interact with genetic predispositions, potentially worsening disease progression by amplifying degenerative processes.

Major Types

Muscular Dystrophies

Muscular dystrophies encompass a group of more than 30 inherited genetic disorders characterized by progressive weakness and degeneration of skeletal muscles, often involving cardiac and as well. These conditions arise from mutations in genes essential for muscle structure and function, leading to a spectrum of severity from early childhood onset to adult presentation. Key subtypes include (DMD), an X-linked recessive disorder caused by mutations in the DMD gene resulting in deficiency; (BMD), a milder allelic variant of DMD with partial function; types 1 and 2 (DM1 and DM2), autosomal dominant conditions stemming from CTG and CCTG repeat expansions in the DMPK and CNBP genes, respectively; and limb-girdle muscular dystrophies (LGMD), a diverse group affecting over 30 genes involved in muscle membrane stability and repair, such as those encoding sarcoglycans or calpain-3. The of dystrophies centers on disruption of the dystrophin-glycoprotein complex (DGC), a assembly that links the intracellular to the , thereby stabilizing the during . In DMD and BMD, absence or dysfunction of —encoded by the largest human , DMD—impairs this linkage, rendering muscle fibers susceptible to mechanical stress, calcium influx, and oxidative damage, which trigger , chronic inflammation, and eventual replacement of muscle tissue with fibrotic and . Similar mechanisms operate in other subtypes, where defects in DGC components (e.g., sarcoglycans in LGMD) or unrelated pathways (e.g., toxicity in ) lead to sarcolemmal instability, fiber breakdown, and progressive muscle wasting, often compounded by secondary mitochondrial dysfunction and impaired regeneration. Dystrophin's role can be conceptualized as maintaining sarcolemmal integrity by anchoring F-actin filaments to via the DGC, preventing membrane tears that exacerbate muscle pathology. Clinically, muscular dystrophies manifest with proximal , affecting the shoulders, hips, and thighs, which impairs and daily activities; in DMD, characteristic features include calf due to fibrofatty infiltration, Gowers' sign (use of hands to rise from the floor), and early loss of ambulation by age 12, alongside respiratory insufficiency and . BMD presents later, with slower progression allowing ambulation into adulthood, while features —delayed muscle relaxation after contraction—manifesting as grip stiffness, in addition to distal and facial , cataracts, and systemic involvement like cardiac arrhythmias. LGMD variants typically show symmetrical proximal without , with onset varying from childhood to mid-adulthood, and may spare or involve depending on the specific defect. Onset ranges from infancy in severe congenital forms to late adulthood in milder subtypes, with complications including , joint contractures, and ventilatory failure in advanced stages. Prevalence varies by subtype, with DMD affecting approximately 1 in 5,000 male births worldwide, making it the most common and severe form, while BMD occurs in about 1 in 18,000-30,000 males; type 1 has a prevalence of 1 in 8,000 globally, and LGMD subtypes collectively impact 1 in 50,000-100,000 individuals. These disorders predominantly affect males in X-linked forms like DMD and BMD but occur equally in both sexes for autosomal types. , including or next-generation sequencing of relevant genes, confirms diagnosis by identifying causative mutations.

Ocular Dystrophies

Ocular dystrophies encompass a group of inherited disorders primarily affecting the and , leading to progressive degeneration of their layers or cells and resultant impairment through opacity, structural disruption, or photoreceptor loss. These conditions are distinct from age-related , as they involve hereditary genetic abnormalities rather than environmental or aging factors alone. The most clinically significant are the corneal dystrophies, classified by the International Committee for the Classification of Corneal Dystrophies (IC3D) into anterior epithelial, stromal, and posterior endothelial categories, with stromal and endothelial types being predominant in causing severe visual loss. Key corneal types include Fuchs' endothelial (FECD), which affects the posterior cornea; (LCD), an epithelial-stromal dystrophy; granular corneal dystrophy (GCD), also epithelial-stromal; and macular corneal dystrophy (MCD), a stromal dystrophy. FECD involves endothelial dysfunction and excrescences known as guttae on . LCD features interweaving lattice-like deposits in the and epithelium, while GCD presents with discrete crumb-like opacities, both often linked to mutations in the TGFBI gene on chromosome 5q31. MCD, in contrast, results from CHST6 gene mutations and is characterized by diffuse stromal clouding due to accumulation. Pathophysiologically, these dystrophies arise from abnormal protein or deposition that disrupts corneal transparency and architecture. In TGFBI-associated dystrophies like LCD and GCD, mutant keratoepithelin (encoded by TGFBI) forms insoluble or aggregates in the , leading to stromal haze and epithelial erosions. FECD centers on progressive endothelial cell loss, impairing fluid pumping and causing corneal , with genetic contributions from TCF4 expansions or COL8A2 . MCD involves defective sulfation of keratan sulfate, resulting in non-sulfated buildup throughout the , , and , which scatters light and thins the . These deposits are typically bilateral and symmetric, with patterns autosomal dominant for most (e.g., FECD, LCD, GCD) and recessive for MCD. Clinically, corneal ocular dystrophies manifest as progressive corneal clouding, often beginning in or early adulthood, with symptoms including , , glare, and recurrent erosions. In FECD, early guttae are , but advanced stages cause morning stromal and bullae formation, typically requiring intervention by the sixth . LCD and GCD progress from superficial opacities and erosions in childhood or to stromal involvement and vision loss by the fourth or fifth , with GCD type 2 () showing accelerated progression after trauma. MCD presents earliest with central haze in the first or second , leading to severe bilateral vision impairment by the third , often with minimal pain but prominent . All types are slowly progressive and noninflammatory. These corneal disorders are rare overall, though prevalence varies by type and population. FECD is the most common corneal dystrophy in Western populations, affecting approximately 4% of individuals over age 40 , with higher rates in females and Caucasians. In contrast, LCD, GCD, and MCD are rarer, with U.S. estimates of 5-10 cases per million, though GCD type 2 reaches 1 in 1,800 in some Asian cohorts like . Management often culminates in , such as endothelial keratoplasty for FECD or penetrating keratoplasty for stromal types, to restore clarity.

Retinal Dystrophies

Retinal dystrophies are a heterogeneous group of inherited disorders primarily affecting the photoreceptor cells (rods and cones) or the , leading to progressive degeneration of the and vision impairment. These conditions result from mutations in genes involved in phototransduction, retinal structure, or metabolism, with patterns including autosomal dominant, recessive, and X-linked inheritance. Common subtypes include (RP), a group of disorders characterized by initial night blindness and loss progressing to ; (LCA), a severe early-onset form causing profound from infancy; and cone-rod dystrophy (CRD), which primarily affects cones first, leading to central vision loss, , and , followed by rod involvement and problems. Pathophysiologically, dystrophies involve apoptotic of photoreceptors due to genetic defects, such as in RHO (for ) disrupting function or RPE65 (for LCA) impairing the . In CRD, genes like ABCA4 or GUCY2D lead to toxic buildup of or impaired cyclic GMP signaling, causing degeneration and secondary loss. These changes result in retinal thinning, bone spicule pigmentation (in ), and eventual legal blindness in many cases, often by mid-adulthood. Symptoms typically emerge in childhood or adolescence, progressing slowly with complications like cataracts or . Prevalence of dystrophies varies, with affecting about 1 in 4,000 individuals worldwide, LCA around 1 in 30,000-80,000 births, and CRD approximately 1 in 40,000. relies on , , and . Management includes low-vision aids, supplementation (for some cases), and emerging therapies like gene replacement (e.g., for RPE65-related LCA).

Other Dystrophies

Other dystrophies encompass a range of hereditary conditions affecting non-muscular and non-ocular tissues, manifesting as progressive structural or functional degeneration due to genetic abnormalities. These primarily involve integumentary structures like nails and teeth, as well as skeletal and multisystem tissues, and are distinct from acquired degenerations secondary to systemic diseases (though the term "dystrophy" is sometimes applied loosely to such cases). Examples include nail dystrophies and skeletal dystrophies, highlighting the term's application across diverse organ systems. Nail dystrophies in this context refer to inherited abnormalities in nail formation, such as those in nail-patella syndrome (NPS), an autosomal dominant disorder caused by mutations in the LMX1B gene, leading to dysplastic (triangular lunulae, ridging), absent or hypoplastic patellae, , and changes that can cause or renal failure. Another example is hereditary dysplasia, involving isolated or syndromic nail fragility and ridging due to gene mutations. These conditions arise from defects in nail matrix development and keratinization, resulting in brittle, ridged, or absent , often with associated skeletal or renal involvement in syndromes like NPS. of NPS is approximately 1 in 50,000 births, while isolated hereditary nail dystrophies are rarer. Skeletal dystrophies, such as asphyxiating thoracic dystrophy (ATD, also known as Jeune syndrome), are rare autosomal recessive ciliopathies caused by mutations in genes like DYNC2H1 or IFT80, affecting and . ATD features a narrow , , and micromelia, leading to respiratory insufficiency in infancy due to restricted expansion, with survivors at risk for renal or hepatic disease. involves disrupted intraflagellar transport in primary cilia, impairing proliferation and . Prevalence is estimated at 1 in 100,000-130,000 births. Dental enamel dystrophies, like amelogenesis imperfecta (), result from mutations in genes such as AMELX or , causing hypoplastic, hypomineralized, or hypomaturation enamel defects that lead to discolored, pitted, or thin prone to fracture and caries. AI affects approximately 1 in 700-14,000 individuals, depending on subtype and population. Across these dystrophies, inheritance is typically Mendelian, with low population prevalence but significant impact on affected individuals, including cosmetic, functional, and systemic complications. Management focuses on , such as orthopedic interventions for skeletal issues, renal monitoring in NPS, or dental restorations in AI, alongside . Conditions like HIV-associated , scleroderma-related esophageal changes, or chronic kidney disease-induced , while sometimes termed "dystrophies," represent acquired degenerations and fall outside the strict hereditary definition used here.

Diagnosis

Clinical Assessment

The clinical assessment of dystrophies begins with a detailed patient history to identify potential hereditary patterns, often involving the construction of a family pedigree to trace inheritance modes such as autosomal dominant, recessive, or X-linked, which are common in conditions like Duchenne muscular dystrophy or corneal dystrophies. Key historical elements include the age of symptom onset, which varies widely—for instance, early childhood in Duchenne muscular dystrophy versus adulthood in Fuchs endothelial corneal dystrophy—the rate of progression, typically slow and insidious, and associated symptoms such as progressive muscle weakness, delayed motor milestones, or vision changes like photophobia, blurred vision, night blindness, or peripheral vision loss. Physical examination focuses on targeted evaluations tailored to the suspected dystrophy type. In muscular dystrophies, muscle power is systematically assessed using the Medical Research Council (MRC) scale, a standardized 0-5 grading system where 5 indicates normal strength against full resistance and 0 denotes no contraction, often revealing proximal weakness patterns such as in the hips and shoulders. For ocular dystrophies, an ophthalmologic exam employs slit-lamp biomicroscopy to detect corneal opacities, guttata, or endothelial changes in corneal types, while fundus examination and visual field testing are used for retinal dystrophies to identify pigmentary changes, macular abnormalities, or field defects; (ERG) assesses retinal function. Dermatologic inspection may reveal associated skin or nail abnormalities in certain forms like nail-patella syndrome. Clinicians must recognize red flags that may indicate non-dystrophic mimics, such as asymmetric or progression, which contrast with the typical symmetric and gradual involvement in most dystrophies and could suggest alternative diagnoses like or inflammatory myopathies. A multidisciplinary approach is essential from the outset, involving neurologists for neuromuscular evaluation, ophthalmologists for visual assessments, and geneticists for analysis and counseling to guide subsequent confirmatory testing.

Laboratory and Imaging Techniques

Laboratory and imaging techniques play a crucial role in confirming the of dystrophies by providing molecular, histological, and structural evidence that complements clinical findings. is often the first-line confirmatory approach, particularly for hereditary forms such as dystrophies. For conditions involving trinucleotide repeat expansions, such as myotonic dystrophy type 1 (DM1), (PCR) methods, including repeat-primed PCR, are used to detect and quantify CTG repeat expansions in the DMPK , with expansions typically exceeding 50 repeats indicating pathogenicity. In (DMD), next-generation sequencing (NGS) enables comprehensive analysis of the DMD , identifying deletions and duplications, which account for approximately 70% of cases, as well as point mutations and other variants, with (MLPA) often integrated for copy number variant detection prior to full sequencing. Targeted NGS gene panels are increasingly employed for broader dystrophy subtypes, allowing simultaneous screening of multiple genes associated with or ocular dystrophies to improve diagnostic yield and facilitate testing. Muscle biopsy remains a key invasive technique for histopathological evaluation, especially when is inconclusive or to assess protein expression. Histological examination typically reveals characteristic dystrophic changes, including marked variation in muscle fiber size (with both hypertrophic and atrophic fibers), scattered of muscle fibers, and regenerative attempts evidenced by basophilic fibers with internalized nuclei. (IHC) on biopsy samples is essential for detecting protein deficiencies; for instance, in DMD and , staining shows absent or significantly reduced expression in sarcolemmal membranes of non-necrotic fibers, confirming the when correlated with genetic findings. These features distinguish dystrophic processes from other myopathies, though biopsy utility has decreased with advances in noninvasive , it provides direct evidence of muscle in ambiguous cases. Imaging modalities offer noninvasive visualization of tissue changes, aiding in disease staging and subtype differentiation. Magnetic resonance imaging (MRI) is widely used in muscular dystrophies to quantify progressive muscle degeneration, particularly through T1-weighted sequences that highlight fat infiltration as hyperintense areas, reflecting replacement of functional muscle by in affected groups like the lower limbs. Quantitative MRI techniques, such as Dixon methods, enhance accuracy in measuring fat fraction compared to standard T1-weighted imaging, correlating with clinical severity in conditions like . For ocular dystrophies, particularly corneal variants, (OCT) provides high-resolution cross-sectional imaging of corneal layers, revealing abnormalities such as irregular epithelial duplication or stromal deposits that characterize dystrophies like macular ; for retinal dystrophies, OCT assesses macular and retinal layer thickness, while fundus autofluorescence and ERG evaluate pigmentary and functional changes. Electrophysiological studies, including electromyography (EMG), are valuable for detecting functional abnormalities in specific dystrophy subtypes. In , needle EMG characteristically identifies myotonic discharges—spontaneous, repetitive potentials with a waxing-and-waning pattern in amplitude and frequency (typically 20-80 Hz)—originating from muscle fibers, which are more prominent in DM1 than DM2 and aid in confirming even in mildly affected muscles. These discharges are nonspecific but, when widespread, strongly support the in the context of clinical features, helping differentiate myotonic dystrophies from other neuromuscular disorders.

Management

Supportive Therapies

Supportive therapies for dystrophies focus on alleviating symptoms, preserving function, and enhancing without addressing underlying genetic causes. These interventions are tailored to the progressive nature of the conditions and often involve multidisciplinary teams including physical therapists, nutritionists, and psychologists. Early initiation of such therapies can delay complications and improve daily living for affected individuals across various dystrophy types, such as and ocular forms. Physical and occupational therapies play a central role in managing mobility and daily activities, particularly in muscular dystrophies. Physical therapy incorporates low-impact exercises and routines to maintain muscle flexibility, prevent contractures, and support ambulation for as long as possible. For instance, in (DMD), regular combined with passive helps preserve joint range of motion and strength. Occupational therapy assists with adaptive strategies, such as using assistive devices, and in muscular types, like ankle-foot braces provide structural support to weakened limbs, reducing fall risk and fatigue. Nutritional support addresses common issues like and growth delays, especially in progressive muscular dystrophies. High-protein diets are recommended to counteract muscle wasting and support overall energy needs, with intake often adjusted based on assessments. In DMD, where swallowing difficulties and reduced caloric requirements can lead to undernutrition, tailored meal plans emphasize nutrient-dense foods to promote and health. Additionally, for respiratory complications in advanced DMD, aids such as bilevel (BiPAP) machines assist with ventilatory failure by improving airflow and reducing fatigue during sleep or rest. Pain management strategies target discomfort from muscle strain, joint issues, or tissue changes common in dystrophies. In types, analgesics like acetaminophen and nonsteroidal drugs (NSAIDs) are used to relieve myalgias and associated with overuse or immobility. For ocular dystrophies involving corneal involvement, such as Fuchs' endothelial dystrophy, lubricating or ointments provide symptomatic relief from irritation and dryness. These approaches are monitored through regular clinical assessments to balance efficacy and side effects. Psychosocial support is essential for coping with the emotional and social burdens of progressive in dystrophies. Counseling and help individuals and caregivers address anxiety, , and adjustment challenges arising from loss of independence. In DMD, for example, structured psychosocial programs across the lifespan promote and facilitate access to networks, improving outcomes. Screening for emotional at routine visits ensures timely interventions.

Targeted Interventions

Targeted interventions for dystrophy aim to address underlying etiologies, such as genetic mutations or inflammatory processes, to alter disease progression rather than merely manage symptoms. Pharmacological approaches, particularly corticosteroids, form the cornerstone for muscular dystrophies like (DMD). Daily administration, at doses of 0.75 mg/kg, delays the loss of ambulation by approximately 2-3 years through anti-inflammatory effects that preserve muscle strength and function. Similarly, , an antisense oligonucleotide approved by the FDA in 2016, induces exon 51 skipping in DMD patients with amenable mutations, enabling partial production to mitigate muscle degeneration. Surgical interventions target structural complications in specific dystrophies. For advanced corneal dystrophies, such as endothelial corneal dystrophy, penetrating or endothelial keratoplasty replaces diseased corneal tissue, restoring in severe cases where opacities impair function; emerging non-surgical options, including eye drop therapies like DT-168, are in early clinical trials as of 2025 and show promise for slowing progression. In muscular dystrophies like DMD, posterior addresses , reducing the rate of forced decline by stabilizing the spine and improving respiratory function postoperatively. Emerging gene therapies focus on correcting genetic defects. An example is Elevidys (delandistrogene moxeparvovec), an AAV-based gene therapy approved by the FDA for ambulatory DMD patients aged 4 years and older with confirmed dystrophin gene mutations; as of November 2025, its indication is limited to ambulatory patients due to risks of acute liver injury, including fatal cases in non-ambulatory individuals, and includes a boxed warning requiring monitoring. CRISPR-Cas9-based editing targets dystrophin gene mutations in DMD, with ongoing clinical trials demonstrating potential for sustained dystrophin restoration in preclinical models and early human studies. For myotonic dystrophy type 1, antisense oligonucleotides (ASOs) reduce toxic CUG repeat RNA accumulation, showing promise in preclinical and phase 1/2 trials for improving muscle strength without significant toxicity. Outcomes of these interventions vary by dystrophy type and timing. , another option for DMD, is associated with delayed onset of and longer preservation of left ventricular systolic function compared to , though both carry risks like . These therapies are often used adjunctively with supportive care to optimize long-term benefits.