User:Joflaher/sandbox

Childhood-onset systemic lupus erythematosus (i.e., cSLE), also termed juvenile-onset systemic lupus erythematosus, juvenile systemic lupus erythematosus, and pediatric systemic lupus erythematosus, is a form of the chronic inflammatory and autoimmune disease, systemic lupus erythematosus (i.e., SLE), that develops in individuals before they reach 18 years old.^[1] Early-onset systemic lupus erythematosus is often used to designate a subset of cSLE patients who are younger than 5 years old; these patients tend to have a more severe form of cSLE than older children.^[2]

cSLE does not include neonatal lupus erythematosus (nSLE). nSLE is a SLE-like disease that is present in infants at birth. It is caused by certain antinuclear antibodies, e.g., the immunoglobulin G types of the anti-SSA/Ro autoantibodies (such as anti-Ro/SS-A and anti-La/SS-B) and anti-nRNP (also termed anti-U1RNP). These antibodies form in the mother and pass from her circulation through the placenta to the fetus where they cause an often severe form of SLE that is evident in the fetus and newborn child. Most of the disorders caused by these antibodies disappear spontaneously within months as the antibodies are naturally cleared from the infant. However, one disorder, congenital heart block, often persists and requires implantation of an artificial cardiac pacemaker into the fetus or the infant. Hydroxychloroquine (given to the mother on her 6th and 10th gestational weeks) or intravenous immunoglobulin therapy (given the mother on her 14 and 18 gestational weeks) can significantly reduce the development of this heart block in the fetus. The mothers of nSLE-afflicted offspring have in about half of the cases SLE or another autoimmune disease.^[3][4]

SLE involves inflammation-based injuries in one or, far more commonly, many tissues and organs.^[5] It is caused by the afflicted individuals' production of antibodies that target nuclear and cytoplasmic self-antigens.^[6] Worldwide, the prevalence of cSLE is 1.9–25.7 per 100,000 children and its incidence is 0.3–0.9 per 100,000 per year.^[7] While there are similarities between the childhood and adult forms of SLE (i.e., aSLE), cSLE has several characteristics that make it a clinical entity distinct from aSLE. For example, cSLE has a more aggressive disease onset and course, more frequent disease exacerbations, more severe organ damages, and a higher mortality rate than aSLE.^[1][6][7]

Presentation

cSLE occurs more frequently in Black, Asian, Hispanic, and Native American than Caucasian populations^[8][9] and is more frequently diagnosed in individuals from urban than rural areas.^[7] The median age at the onset of cSLE was 12.6 years in a review of 196 cases conducted in the United Kingdom.^[10] Patients with cSLE may present with tissue-injuring and blood vessel-injuring (termed lupus vasculitis) inflammation in the: a) kidneys, causing various types of kidney damages e.g., lupus nephritis and kidney failure, and thereby hypertension, i.e., high blood pressure;^[1][11][12] b) central nervous system, causing headaches, seizures, cerebrovascular disease, strokes, and the encephalopathies of neuropsychiatric systemic lupus erythematosus such as mood disorders, cognitive disorders, and psychoses;^[13][14][15] c) lung, causing pleuritis, pneumonitis (termed acute lupus pneumonitis), pulmonary hypertension, pulmonary hemorrhages, and a form of restrictive lung disease in which the lung has shrunk in size (this condition is termed the "shrinking lung syndrome", see rheumatoid lung disease); d) gastrointestinal tract, causing peritonitis and intestinal pseudo-obstructions;^[16][17] e) heart, causing pericarditis, myocarditis, endocarditis, and cardiac tamponade (i.e., pericardial fluid that compresses the heart); f) pancreas, causing pancreatitis, hyperlipidemia and, as a long-term consequence of hyperlipidemia, atherosclerosis and myocardial infarctions (i.e., heart attacks);^[1][17][18] g) joints, causing non-deforming arthritis and in rare cases the deforming arthritis, Jaccoud arthropathy; i) skeletal muscles, causing muscle pain and tenderness that may be accompanied by the same types of rashes, arthritides, and arthralgias that occur in the inflammatory muscle disease, dermatomyositis;^[1] and/or h) skin and mucous membranes, causing active and chronic lesions such as a malar rash, discoid rash (see discoid type rash), photodermatitis, oral/nasopharyngeal ulcers,^[19] cutaneous small-vessel vasculitis skin lesions,^[9] and in rare cases chilblain lupus erythematosus.^[20] cSLE may also present as autoimmune-induced decreases in the blood levels of platelets termed immune thrombocytopenic purpura), red blood cells termed autoimmune hemolytic anemia, leukocytes termed leukopenia, neutrophils termed neutropenia (neutrophils are a type of leukocyte), and lymphocytes termed lymphopenia.^[1][21] Patients with cSLE may also develop thrombotic microangiopathy, a severe disease caused by the aggregation of blood platelets in, and thereby partial occlusion of, the blood flow to and dysfunction of multiple organs including in particular the brain and kidneys. Individuals with cSLE-related thrombotic microangiopathy may also exhibit thrombocytopenia and/or hemolytic anemia.^[1][22] Fatigue is also a frequent complaint of children presenting with cSLE.^[23][24] Finally, cSLE patients on rare occasions develop functional asplenia (i.e., a poorly functioning spleen) that increases their susceptibility to infections.^[25]

Studies have shown that the presentations and extents of disease differ in patients with cSLE and aSLE. For example, cSLE afflicts 4–5 females to 1 male while aSLE afflicts 9 females to 1 male; cSLE involves the kidneys in 60–80% and aSLE in 35–50% of cases; cSLE involves the central nervous system in 20–50% and cSLE in 10–25% of cases; cSLE involves the lung in 15–40% and aSLE in 20–90% of cases; and SLE involves the joints in 60–70% and aSLE in and 80–95% of cases. cSLE also has a more aggressive course and requires more intensive therapy than aSLE; genetic disorders more often underlie the development of cSLE than aSLE (see "Genetics" in next section);^[6] and drug-induce SLE has been reported less frequently in cSLE than aSLE (see "Drugs" next section).^[26] There are also some differences is the presentation of cSLE in different populations. For example, a study conducted in Japan reported that patients diagnosed with cSLE presented with a malar rash (73.1% of cases), discoid rash (17.7%), photosensitivity (23.1%), arthritis (33.3%), serositis (9.7%), hemolytic anemia (12.4%), and leukopenia (52.2%).^[27] In contrast, patients in Turkey diagnosed with cSLE presented with a malar rash (60.8%), discoid rash (11.8%), photosensitivity (44.1%), arthritis (46.1%), serositis (16.7%), hemolytic anemia (17.6%), and leucopenia (33.3%).^[28]

Causes

Inflammation

SLE is caused by a not yet well understood generation of inflammation-inducing antibodies (termed autoantibodies) that attack an individual's own antigens.^[29] These autoantibodies, none of which are present in all cases of SLE, include the: a) antinuclear (i.e., ANA) and anti-dsDNA antibodies; b) anti-Sm, anti-RNP, anti-SSA, and anti–SS-B antibodies (anti-SSA and anti-SS-B antibodies are associated with less severe forms of cSLE);^[30]) c) antiphospholipid autoantibodies including the lupus anticoagulant, anti-cardiolipin, and anti-apolipoprotein autoantibodies; and d) anti-histone antibodies (anti-histone antibodies are associated with drug-induced SLE). When bound to their target antigens, these autoantibodies form immune complexes which attract T cells, B cells, and other inflammation-inducing leukocytes. In addition, the antibody-antigen complexes are engulfed by plasmacytoid dendritic cells that then produce type I interferons which act to further promote the inflammation responses.^[31] More than 95% of individuals with cSLE display a type I IFN signature, i.e., increased blood or tissue levels of the messenger RNAs (i.e., mRNAs) for the type 1 interferons.^[5]

Gene mutations

Studies of identical twins (i.e., twins that develop from the same fertilized egg) and genome-wide association studies have identified numerous genes that when having certain types of mutations cause aSLE and/or cSLE.^[6][32][33] The genes that cause aSLE are termed as acting in a "mongenic" or "single-gene" manner.^[1] They include 5 that are classified as inborn errors of immunity genes,^[34][35][36] i.e., the DNASE1L3, TREX1, IFIH1, Tartrate-resistant acid phosphatase, and PRKCD genes) and 29 other genes, i.e., NEIL3, TMEM173, ADAR1, NRAS, SAMHD1, SOS1, FASLG, FAS receptor gene, RAG1, RAG2, DNASE1, SHOC2, KRAS, PTPN11, PTEN, BLK, RNASEH2A, RNASEH2B, RNASEH2C, Complement component 1qA, Complement component 1qB, Complement component 1r, Complement component 1s, Complement component 2, Complement component 3, UNC93B1 (Mutations in the UNC93B1 gene cause either SLE or the chilblain lupus erythematosus variant of SLE.^[20]), TLR7, and two complement component 4 genes, C4A and C4B.^{[6][20][34][37][38]} The C4A and C4B genes code respectively for complement component A and complement component B proteins. The two proteins made by these genes combine to form the complement component 4 protein which plays various roles in regulating immune function. Individuals normally have multiple copies of the C4A and C4B genes but develop SLE if they have a mutation in one of them that significantly reduces the number of its copies.^[39][40] While it is suggested that any of these gene mutations may cause cSLE, only a few have been documented to do so. These monogenetic mutations include those in

SAT1 cause X-linked childhood-onset systemic lupus erythematosus transmitted from the heterozygous unaffected mother to her two sons PMID: 35977808

Mutations in a wide range of other genes do not by themselves cause SLE can act in concert with other genes, environmental factors, or unknown factors in some but not other populations (e.g., cause SLE in individuals of Chinese but not European descent) to cause SLE or an SLE-like syndrome.^[33][41] The development of a genetically-regulated trait or disorder that is dependent on the inheritance of two or more mutated genes is termed oligogenic inheritance or polygenic inheritance.^[42][43] The article published by Sestan, et al.,^[6] lists more than 110 genes that must act in cooperation with other factors to promote the development of aSLE and/or cSLE.

Drugs

Drug-induced SLE is an autoimmune disease in which individuals develop clinical features similar to that in SLE after taking a drug. It is estimated to represent 10% to 12% of all SLE cases.^[26] Although there are no established criteria for diagnosing drug-induced SLE, most reports have used the following criteria: afflicted individuals had a sufficient and continuing exposure to the drug, at least one symptoms that occurs in SLE, no history of SLE symptoms SLE before starting the drug, and resolution of their drug-induced symptom(s) within weeks to months after discontinuing the offending drug.^[44] The American College of Rheumatology has suggested at least one serologic and one non-serological criterium (see below section on "Diagnosis of cSLE") be included in the criteria used to diagnose drug-induced SLE.^[26] The VigiBase drug safety data repositor diagnosed 12,166 cases of drug-induced aSLE recorded between 1968 and 2017. Among the 118 drugs causing these aSLE cases, five main drug classes were most often associated with the development of aSLE: a) inhibitors of tumor necrosis factor. b) antiarrhythmic agents such as procainamide or quinidine; c) antihypertensive agents such as hydralazine, captopril, or acebutolol; d) antimicrobial agents such as minocycline, isoniazid, carbamazepine, or phenytoin; e) anticonvulsants such as carbamazepine; and f) polyinosinic:polycytidylic acid (an artificial interferon inducer).^[44]

There are fewer reports of drug-induce SLE in children than adults. In a review of 65 cases described in the English language, Kaya Akca, U. et al., 2024^[26] reported that cSLE was caused by ethosuximide (13 cases), minocycline (12 cases), ethosuximide combined with hydantoin (3 cases), propylthiouracil combined with sulphasalazine (3 cases), carbamazepine (3 cases), cysteamine (2 cases), etanercept (2 cases), isoniazid (2 cases), trimethadione combined with ethosuximide plus hydantoin (2 cases), and single cases of Adalimumab, cefepime, dapsone, doxycycline, griseofulvin, hydantoins, hydralazine, infliximab, interferon alpha, levamisole, minocycline combined with dianette, polyinosinic-polycytidylic acid, procainamide, thiamazole combined with propylthiouracil, topiramate, trimethadione, and zafirlukast. In 3 cases, the offending drug was not identified. The duration of these individuals' drug exposure was (0.2 to 150 months, median of 9 months). The clinical manifestations of their disorder observed in more then 1 patient were: fever (in 50.8% of cases), arthralgia (47.7%), rash (46.2%), arthritis (44.6%), malar rash (23.1%), proteinuria (20.%), lymphadenopathy (16.9%), myalgia (15.4%), weight loss (12.3%), anemia (9.2%), edema of the extremities and face (9.2%), fatigue (9.2%), lupus nephritis (9.2%), nausea (9.2%), pleural effusions (9.2%), headaches 5 (7.7%), hepatosplenomegaly or just splenomegaly (7.7%), malaise (7.7%), joint stiffness felt when awakening from sleep (7.7%); chest pain (6.1%), hematuria (6.1%), leukopenia (6.1%), myocarditis and/or pericarditis (6.1%), pneumonia (6.1%), generalized weakness (6.1%), oral ulcers, (6.1%), abdominal pain (4.6%), reductions in the number of almost all blood cells termed pancytopenia (4.6%), photosensitivity (4.6%), respiratory distress (4.6%), thrombocytopenia (4.6%), and hepatitis (3.1%).

Vitamin D deficiency

Studies have reported that: vitamin D deficiency often occurs in patients with aSLE; vitamin D levels are particularly low in patients with more active aSLE;^[45][46] and aSLE patients treated with vitamin D have significant reductions in the activity of their disease.^[47] While other studies have not found these results, it is clear that the serum levels of vitamin D are often low, perhaps as a result of having aSLE. This is particularly the case in cSLE.^[48] Vitamin D is obtained by consuming it or its precursors in food and by forming its precursors in the cells of the skin exposed to sunlight (see Vitamin D formation in skin cells).^[49] By binding to its receptor, vitamin D increases calcium absorption from the intestine, increases calcium reabsorption from the kidneys, and regulates the immunological functions of macrophages, T cells, and dendritic cells.^[49][50] In consequence, the low levels of vitamin D in cSLE may cause excessive losses of body calcium, hypocalcemia, low bone density, osteoporosis, increased risk of havine bone fractures,^[48] and reduced ability to suppress tissue inflammatory reactions.^[48][51][52] The factors that tend to lower vitamin D in individuals with SLE include: a) avoidance of sunlight and ultraviolet light exposure because of SLE-related photosensitivity; b) reduced consumption of vitamin D due to the loss appetite caused by SLE itself and/or the medications used to treat SLE (e.g., corticosteroids); c) corticosteroid-indued reductions in vitamin D levels; d) inhibition of the the actions of vitamin D receptors by hydroxychloroquine, a drug which is commonly used to treat SLE; and e) low levels of vitamin D production by lupus nephritis-afflicted kidneys (along with the liver, the kidney forms vitamin D from its precursors that were in the diet or formed by sunlight, see the below section "Treatment for vitamin D deficiency in cSLE").^[48][53]

Diagnosis of cSLE

Systemic Lupus International Collaborating Clinics criteria

The diagnosis of SLE can be challenging because not one its symptoms or biomarkers by themselves are sufficient to indicate that the disease is SLE. Currently, the diagnosis of cSLE (and aSLE) depends on finding a combination of criteria that strongly support this diagnosis.^[2] The Systemic Lupus International Collaborating Clinics (SLICC) is an international group dedicated to studying SLE. This group evaluated the following Clinical and Immunological criteria (i.e., immunological biomarkers) for diagnosing SLE. The group concluded that patients satisfying 4 of the 16 criteria listed below including at least one of the 10 Clinical criterium and one of the 6 Immunologic criterion had a sensitivity (i.e., probability of a positive test result conditioned on the individual truly being positive) of 92.6% and a specificity (i.e., probability of a negative test result, conditioned on the individual truly being negative) of 89.1%. These respective values for aSLE were 94% and 92%.^[54] Patients satisfying these criteria were therefore diagnosed as having cSLE or aSLE.^[55] For further details on these criteria see Petri, M et al^[55] and Fonseca, AR et al.^[54]

Clinical criteria: Individuals exhibiting: 1) lesions that occur in acute cutaneous lupus erythematosus such as a malar rash, toxic epidermal necrolysis, bullae (i.e., large blisters containing serous fluid), maculopapular rashes, photosensitive lupus-like rashes (in individuals who do not have dermatomyositis), or subacute cutaneous lupus erythematosus-like lesions, e.g., scar-like polycyclic annular or plaque-like lesions on the skin most commonly in areas exposed to sunlight; 2) clinical signs found in discoid lupus erythematosus (with or without signs found in lichen planus) such as verrucous lupus erythematosus, lupus erythematosus panniculitis, mucosal lupus (i.e., lupus lesions involving mucus membranes), lupus erythematosus tumidus, or chilblain lupus erythematosus; 3) oral ulcers, i.e., ulcers on the mucus membranes of the nose, palate, tongue, and/or gums that occur in the absence of other causes such as vasculitis, Behçet's disease, Herpes infection, inflammatory bowel disease, reactive arthritis, or the excessive intake of acidic foods; 4) nonscarring alopecia (i.e., diffuse thinning or hair fragility with visibly broken hairs) in the absence of other causes such as alopecia areata, drugs, iron deficiency, and androgenic alopecia; 5) synovitis involving two or more joints plus 30 minutes or more of morning joint stiffness; 6) pleurisy lasting more than one day, a pleural effusion or a pleural rub, serositis of the heart as shown by symptoms of pericardial pain that lasts for more than one day and is lessened by sitting forward, pericardial effusion, pericardial friction rub, or EKG evidence of pericarditis in the absence of other causes such as infection, uremia, or Dressler's syndrome: 7) kidney dysfunction as indicated by a 24 hour urine protein of at least 500 mg or the presence of red blood cell casts; 8) neurologic disorders such as seizures, psychosis, mononeuritis multiplex (in the absence of other causes such as primary vasculitis), myelitis, neuropathy in the peripheral or cranial nerves (that are not due to other causes such as primary vasculitis, infection, or diabetes mellitus), and acute mental confusion in the absence of other causes such as toxic encephalopathy, uremia, or drugs; 9) hemolytic anemia; 10) leukopenia with blood leukocyte levels less than 4,0000 per cubic millimeter (at least once in the absence of other known causes such as Felty's syndrome, drugs, or portal hypertension), or lymphopenia with blood lymphocyte counts less that 1000 per cubic millimeter (in the absence of other known causes such as drugs and infection); and 11) thrombocytopenia with blood platelet counts less than 100,000/ per cubic milliliter in the absence of other known causes such as drugs, portal hypertension, or thrombotic thrombocytopenic purpura.

Immunological criteria: 1) high serum levels of antinuclear antibodies; 2) high serum levels of anti-dsDNA antibodies; 3) high serum levels of anti-Sm antibodies; 4) high blood levels of antiphospholipid antibodies, high blood levels the lupus anticoagulant, a false positive rapid plasma reagin test, or a medium to high titer of IgA, IgG or IgM anti-cardiolipin or anti-β2 glycoprotein I-dependent anti-cardiolipin antibodies; 5) low serum levels of complement C3, complement C4, or total complement activity as measure by the CH50 test; and 6) a positive Direct Coombs test in the absence of hemolytic anemia.

SLICC criteria for lupus nephritis

The SLICC also defined individuals with biopsy-proven lupus nephritis plus elevated blood levels of antinuclear and/or or anti-dsDNA antibodies as having aSLE^[55] or cSLE.^[54]

European League Against Rheumatism/American College of Rheumatology criteria

In 2020, the European League Against Rheumatism (now named the European Alliance of Associations for Rheumatology) in collaboration with the American College of Rheumatology^[56] developed a different set of criteria for diagnosing SLE in patients aged 2-21 years old. They determined that individuals in this age group had SLE if they had: 1) a serum titer of 1:80 or higher for any one of the antinuclear antibodies as measured using cultured HEp-2 cells or other valid measurements of these antibodies^[57] and b) one or more of 7 specified constitutional, hematologic, neuropsychiatric, mucocutaneous, serosal, renal, or musculoskeletal clinical symptoms plus elevated serum levels of antiphospholipid antibodies, the iC3b split product of Complement component 3 and/or 4b split product of Complement component 4, and SLE-specific antibodies. Each of these items received a severity score ranging from 2 to 10 with individuals being diagnosed as having cSLE if they receive a a summary score of 10 or higher. The sensitivity and specificity scores of these criteria in diagnosing SLE in this age group were 84.8 and 82.8, respectively.^[56][58]

Genetic criteria

The diagnosis of cSLE in individuals with SLE-like findings is indicated in individuals with any one of the monogenic gene mutations known to cause cSLE as well as any monogenic mutations such as the many that cause aSLE but are not yet known to case cSLE that future studies find are associated with the development of cSLE (see the above section on Genetics).

Factors suggesting the diagnosis of cSLE

The diagnose of cSLE is suggested in individuals with any symptoms of cSLE who have: a) a family member(s) that has SLE; b) mutations in genes that must interact with other genes to cause SLE (see above section on Genetics);^[6][33] or c) detectable blood and/or blood leukocyte levels of the mRNA for genes activated by the type-1 interferons, e.g., the EPSTI1, IFI44L, LY6E, OAS3, RSAD2 and sialoadhesin genes (the gene for sialoadhesin is termed SIGLEC-1).^[5][59] The abnormal presence of these mRNAs in tissues is sometimes termed the "interferon signature" or "high interferon signature".^[59] These interferon signature mRNAs have been detected in up to 90-95% of individuals with cSLE.^[5][9][60]

Treatment

Individuals with cSLE should be: a) advised to protect themselves against inflammation-inducing ultraviolet light by avoiding, and using sunscreen to block, sunlight;^[61] b) counseled on their nutritional needs (e.g., their diets should be low in salt and, if routine checks indicate their vitamin D blood levels are low, contain supplemental vitamin D); and c) offered mental health services if showing signs of depression, anxiety, and/or ineffective family coping. Furthermore, cSLE patients are infection-prone due to their taking immunosuppressive drugs and/or having functional asplenia (i.e., a poorly functioning spleen).Since infections are a common cause of disease flares and mortality in cSLE, cSLE patients should be encouraged to be immunized against Streptococcus pneumoniae, Neisseria meningitidis, Haemophilus influenzae, Clostridium tetani, and Neisseria meningitidis bacteria and to Influenza B, Hepatitis A, Hepatitis B, Papillomaviridae, (which cause warts and various cancers including cervical cancer), and SARS-CoV-2 viruses. Attenuated vaccines, i.e., vaccines containing live but weakened viruses, such as the varicella, measles, mumps, rubella, MMR (i.e., combined measles, mumps, and rubella), and, if living in and endemic are, yellow fever vaccines, are contraindicated for cSLE patients who are immunosuppressed by their disease and/or treatment with immunosuppressing drugs.^[1][60]

Treatment for vitamin D deficiency in cSLE

Childhood-onset and young adults diagnosed with cSLE commonly have low serum levels of 25(OH)D. 25(OH)D stands for two agents, ergocalciferol (also termed 25-hydroxyvitamin D₂) and calcifediol (also termed 25-hydroxyvitamin D₃) which are commonly measured together. Normal levels of 25(OH)D are 30 to 100 nanogram (i.e., ng) per ml of serum. Patients with serum levels of 25(OH)D below 30 ng per ml should be treated with 50,000 international units of oral cholecalciferol per week for 6 months or longer in order to attain and maintain normal levels of 25(OH)D. This replacement regimen is well-tolerated and significantly decreases patient fatigue and their scores on the Systemic Lupus Erythematosus Disease Activity Index 2000 survey (which rates non-fatigue cSLE symptoms^[62]).^[48][58]

Treatments for drug-induced cSLE

In a review of 65 individuals with cSLE caused by the drugs cited in the above section "Drug", discountenance of taking the responsible drug and treatment with a glucocorticoid in 53.3% of cases, hydroxychloroquine in 8.4% of cases, and cyclophosphamide in 3.3% of cases resulted in improvements in 92.0% of the 63 individuals available for follow-up studies. These improvements usually began shortly after treatment began but in rare cases required several weeks to months to occur.^[26]

Treatments for cSLE not drug-induced

The current treatments for cSLE not drug-induced are based on trials in aSLE which showed that certain drug regimens improved the long-term symptoms and survival but did not produce disease cures in aSLE. Studies are needed to determine if other treatments beside these would prove better treatments than those now used for cSLE.^[63]

Hydroxychloroquine is recommended as first-line therapy to treat all cSLE patients unless they have contraindications to taking it. It is an antimalarial drug that has been found to reduce the fatigue, mucusal and cutaneous symptoms, alopecia, disease flares, and blood lipid levels in cSLE. Since hydroxychloroquine can damage the retina, annual ophthalmology examinations of hydroxychloroquine-takers are needed to assess retinal changes which if present indicate that the drug should be discontinued.^[1] Hydroxychloroquine is taken at daily dosages of 5 or more milligrams (i.e., mg) per kilogram (i.e., kg) of patient weights per day but not exceeding a total of 400 mgs per person per day.^[8][60] Individuals treated with hydroxychloroquine at dosages less than 6.5 mg per kg of body weight per day rarely develop retinal injury.^[1]

Glucocorticoids (e.g., prednisone, prednisolone, hydrocortisone, and methylprednisolone^[64]) are used to suppress the intensity of the inflammatory component of cSLE. Topical glucocorticoid ointments are used to treat mild to moderate skin rashes^[1] while an oral or injectable glucocorticoid is used for non-cutaneous inflammations.^[65] For example, prednisone is used at low doses (equal to or less than 7.5 mg per day), medium doses (greater than 7.5 mg but less than 30 mg per day), or high doses (greater than 30 mg but less than 100 mg per day) to treat mild, moderate, or severe inflammations, respectively, such as those causing neurological, hematologic, and kidney disorders. Pulse dosages of prednisone (250 mg per day for one to a few days) may also be used for moderate to severe inflammations.^[65] Glucocorticoids, particularly when used long-term, cause hyperglycemia, diabetes, hypertension, dyslipidemia, growth suppression, weight gains, abdominal obesity, moon facies, buffalo humps (i.e., humps on the back or nape), thinning of the skin, hirsutism, avascular necrosis of the femur's head, myopathy, adrenal insufficiency, delayed puberty, gastritis, bleeding and ulcers in the gastrointestinal tract, pancreatitis, hypertension, congestive heart failure, insomnia, mood disorders (i.e., depression, anxiety, loss of emotional control, euphoria, hypomania, mania, and psychoses), cataract formation, glaucoma , and increased susceptibility to infections.^[61] Children face a significantly higher risk of corticosteroid-related complications such as cataracts and avascular bone necrosis than adults.^[6][64]

Nonsteroidal anti-inflammatory drugs (i.e., NSAIDs) such as aspirin, naproxen, ibuprofen, indomethacin, tolmetin, and ketoprofen^[66] are useful for treating fevers, arthritis, and small pleural and pericardial effusions in cSLE patients.^[1] The adverse effects of NSAIDs in pediatric patients include ulcers, bleeding, and perforation of the gastrointestinal tract; allergic reactions in the skin; lipodystrophy, and reductions in kidney function such as low glomerular filtration rates, kidney disorders such as interstitial nephritis, renal papillary necrosis, and, in patients with kidney failure, lupus nephritis. (Interstitial nephritis and renal papillary necrosis are rare, idiosyncratic toxic reactions to NSAIDs.) NSAIDs may also be toxic to the central nervous system. For example, indomethacin often produces headaches, aspirin can cause ringing in the ears or dizziness, and ibuprofen or, less frequently, other NSAIDs, may cause aseptic meningitis. Finally, aspirin often causes hepatic toxicity in patients with more severe SLE cases. It is recommended that periodic hematological, renal, and liver function tests be conducted in cSLE patients taking these drugs.^[66]

Methotrexate is used orally or by subcutaneous injection once a week at dosages of 15 to 20 mg per squared meter of body size to reduce the levels of glucocorticoids needed to treat mild to moderate cSLE-induced inflammatory diseases, especially those involving the musculoskeletal system.^[60] It is also used to treat cSLE arthritis that is refractory to NSAIDs.^[1] Methotrexate can cause food intolerance,^[1] liver damage, and bone marrow suppression. It should not be used in patients with significant kidney disease^[1] because it is eliminated primarily by the kidneys and in patients with damaged kidneys it rapidly builds up to reach toxic levels (see adverse effects of methotrexate).^[67]

Mycophenolate mofetil is used at an oral daily dosage of 1200 to 1800 mg per squared meter of body size (maximum daily dosage of 3000 mg per squared meter of body size) as induction and maintenance therapy to treat the proliferative and membranous glomerulonephritis forms of lupus nephritis (see Classification of lupus nephritis), to treat cSLE psychiatric disease, and to reduce the amount of corticosteroids needed to treat moderate to severe inflammatory disease in cSLE. Individuals taking this drug may develop a suppressed bone marrow and an increased susceptibility to infections.^[60]

Cyclophosphamide is used at 500 mg per dose for 6 doses every every 2 weeks over a one month period or six 500 to 750 mg intravenous doses per square meter of body surface for 3 years to treat severe cSLE disease and as induction therapy for lupus nephritis. Patients taking these regimens may develop bone marrow suppression, susceptibility to infections, decreased ovarian reserve (i.e., lower capacity of the ovary to provide egg cells that are capable of being fertilized), sperm abnormalities, and malignancies.^[60]

Rituximab is a monoclonal antibody that is used to treat severe and refractory cases of cSLE. It is given at intravenous dosages of 750 mg per square meter of body surface area twice over 2 week intervals or at 375 mg per square meter body surface area once a week for 4 weeks over a 1 month period. Individuals taking either of these regiments may develop persistent [[hypogammaglobulinemia] and have an increased risk of developing infections and infusion reactions (see Cytokine release syndrome.^[60] Infusion reactions are adverse reactions to the intravenous or subcutaneous infusion of pharmacological or biological substances. These reactions may be mild to moderate (e.g., skin flushing, pruritus, and/or urticaria) that develop during or within several hours after the infusion of rituximab and are easily managed but in severe cases can be life-threatening (e.g.,anaphylaxis) that require immediate medical interventions.^[68]

Belimumab is a monoclonal antibody that inhibits B-cell activating factor and thereby inflammation. It was approved in 2019 by the US Food and Drug Administration to treat the musculoskeletal, cutaneous, and cardiac manifestations of children with cSLE who are more than 5 years old. It is given intravenously to cSLE patients with active disease but should not be given to cSLE patients who have active neuropsychiatric systemic lupus erythematosus disease, have acute severe lupus renal disease, or are taking prednisone at doses greater that 1.5 mg per kg per day. Patients taking belimumab have an increased susceptibility to infections.^[60]

Calcineurin inhibitors, i.e., tacrolimus, cyclosporin, and voclosporin, inhibit the proliferation of T-cells but also have non-immunological actions that may be relevant to cSLE, e.g., they reduce proteinuria, stabilize the cytoskeleton of the podocyte cells in the kidneys' Bowman's capsule, constrict the kidneys' afferent arterioless, and activate the renin–angiotensin system.^[60][69] Studies have shown that these drugs help suppress lupus nephritis in adults when combined with other drugs. For example, a regimen consisting of tacrolimus (4 mg per day), mycophenolate mofetil, and glucocorticoids had a significantly higher response rate in treating adult lupus nephritis than a standard treatment regimen consisting of cyclophosphamide plus glucocorticoids. The incidence of adverse reactions to the two regimens was similar. It has therefore been suggested that regimens including a calcineurin inhibitor may be useful and should be studied for treating lupus nephritis in cSLE patients.^[1][60] Tacrolimus ointment, when Topically applied at a dose of 1 gram per day is used to treat mild to moderate skin rashes in cSLE.^[1]

Renin–angiotensin–aldosterone system inhibitors are angiotensin-converting-enzyme inhibitors (i.e., ACEi), angiotensin receptor blockers (i.e., ARB), aldosterone receptor antagonists (i.e. ARAn), and renin inhibitors some of which have been shown to reduce high blood pressures and proteinuria in aSLE. A preliminary review of 74 children 13-17 years old with lupus nephritis were treated with glucocorticoids with or without an ACEi, ARB, or ARAM. cSLE patients receiving one of the inhibitors for a median time of 375 days showed improvements in their renal function that enabled stopping glucocorticoid treatment; cSLE patients that did not receive one of these inhibitors required a median time of 648 days before kidney function improved enough to stope taking a glucocorticoid. While further studies are needed, the study suggested that taking an ACEi, ARBm, or ARAn has the desirable effect of decreasing glucocorticoid intake and thereby the toxic effects of long-term glucocorticoid consumption.^[70]

Bortezomib given intravenously or subcutaneously reversed or greatly reduced cSLE-related encephalopathic neuropsychiatric disorders in a recent study of 5 patients. These disorders were auditory hallucinations and insomnia in all 5 patients, suicidal ideation in 4 patients, visual hallucinations in 3 patients, homicidal ideation in 2 patients, hyper-religiosity along wit fabricated languages in 2 patients, high combativity in 2 patients, mania in 1 patient, a conversion disorder with echolalia, tinnitus, and tics in 1 patient, and anxiety along with a mood disorder in 1 patient. All 5 patients developed hypogammaglobulinemia (immunoglobulin G less than 500 mg per deciliter of blood) that requiring replacing the immunoglobulin for the 1-10 years that the patients were treated with bortezomib. Patient 3 had a brief episode of hypotension after the administration of intravenous bortezomib. Further studies are needed to confirm and expand these promising results.^[71]

Treatment of lupus nephritis

Lupus nephritis not only leads to kidney failure, it is also one of the most common as well as most serious and potentially lethal disorders in cSLE and aSLE.^[5] A 2002 report by a consensus conference of nephrologists, pathologists, and rheumatologists separated lupus nephritis into 6 classes in order to redefine the severity of its various classes and provide a pathophysiology-based approach for the diagnosis and treatment of the 6 classes.^[72] These classes and their respective treatments for patients with cSLE or aSLE are:^[1][7][72]

• Class I, also termed minimal mesangial glomerulonephritis, has a good prognosis without specific treatment.
• Class II, also termed mesangial proliferative glomerulonephritis, presents with microscopic hematuria and/or proteinuria. It generally responds to high dosages of glucocorticoids.
• Class III, termed focal proliferative nephritis, presents with hematuria, proteinuria, the nephrotic syndrome, and/or hypertension. It is treated with a glucocorticoid and an immunosuppressant drug such as mycophenolate mofetil or cyclophosphamide.
• Class IV, termed diffuse proliferative nephritis, presents with hematuria, proteinuria, and hypertension. It is treated with a glucocorticoid and an immunosuppressant drug such as mycophenolate mofetil or cyclophosphamide.
• Class V, termed membranous glomerulonephritis, presents with proteinuria and on occasion the nephrotic syndrome and anasarca (i.e., generalized edema). It has a better prognosis than Class III or IV disease.
• Class VI, termed advanced sclerosing lupus nephritis or Glomerulosclerosis, is poorly responsive to all therapies but progresses to kidney failure very slowly.

Class III and IV (i.e., the proliferative lupus nephritises) have the worst prognosis and account for up to 75% of all lupus nephritis cases in cSLE. The International Society of Nephrology and Renal Pathology Society revised this classification system in 2018 by dividing each class into levels of severity with increasing scores and defining its severity and best treatments based on total scores. We use the 2002 classification because the studies reported here were based on it.^[7][72]

Prognosis

The prognosis of cSLE and aSLE have improved over the past 50 years. The 10-year survival rate of cSLE patients treated in rheumatology multidisciplinary clinics rose from 78% in the 1970s to 85% in the 2000s.^[73] Similarly, the 10 year survival rates in Japan were 92.3% for 1980-1994 and 98.3% for 1995-2006.^[27] Recent studies using the standardized mortality ratio method reported that persons with cSLE and aSLE had respectively 18.3% and 3.1% higher mortality rates than their age-matched general populations^[74] Another study found that cSLE patients had a 19% higher mortality than their age-matched general population.^[7] The prognosis for progression of lupus nephritis has also improved since the 1980s with recent studies finding that the ten year kidney survival time (i.e., time from diagnosis to the development of kidney failure) of 86%. Nonetheless, patients with cSLE have a 19-fold higher risk of dying than the age-matched population while patients with aSLE have an 8-times higher mortality rate than their age-matched population.^[7][75] Since delayed diagnosis and treatment of lupus nephritis results in higher incidences of kidney failure,it should be quickly diagnosis and properly treated.^[5] As more patients have survived well past the early course of their disease, premature atherosclerosis has increasingly contributed to the mortality in cSLE and aSLE.^[9]

References

1. Sura A, Failing C, Co DO, Syverson G (June 2024). "Childhood-Onset Systemic Lupus Erythematosus". Pediatrics in Review. 45 (6): 316–328. doi:10.1542/pir.2023-006011. PMID 38821900.
2. Lee WF, Fan WL, Tseng MH, Yang HY, Huang JL, Wu CY (August 2022). "Characteristics and genetic analysis of patients suspected with early-onset systemic lupus erythematosus". Pediatric Rheumatology Online Journal. 20 (1): 68. doi:10.1186/s12969-022-00722-6. PMC 9375402. PMID 35964089.
3. Derdulska JM, Rudnicka L, Szykut-Badaczewska A, Mehrholz D, Nowicki RJ, Barańska-Rybak W, Wilkowska A (June 2021). "Neonatal lupus erythematosus - practical guidelines". Journal of Perinatal Medicine. 49 (5): 529–538. doi:10.1515/jpm-2020-0543. PMID 33470961. {{cite journal}}: no-break space character in |title= at position 29 (help)
4. Liszewska A, Woźniacka A (December 2022). "Neonatal lupus erythematosus - prevention is better than cure". Postepy Dermatologii I Alergologii. 39 (6): 1021–1026. doi:10.5114/ada.2022.122601. PMC 9837598. PMID 36686025.
5. Cody EM, Brunner HI (February 2022). "Biomarkers in Childhood-Onset Systemic Lupus Erythematosus". Rheumatic Diseases Clinics of North America. 48 (1): 271–285. doi:10.1016/j.rdc.2021.09.003. PMID 34798952.
6. Sestan M, Kifer N, Arsov T, Cook M, Ellyard J, Vinuesa CG, Jelusic M (July 2023). "The Role of Genetic Risk Factors in Pathogenesis of Childhood-Onset Systemic Lupus Erythematosus". Current Issues in Molecular Biology. 45 (7): 5981–6002. doi:10.3390/cimb45070378. PMC 10378459. PMID 37504294.
7. Pennesi M, Benvenuto S (October 2023). "Lupus Nephritis in Children: Novel Perspectives". Medicina (Kaunas, Lithuania). 59 (10). doi:10.3390/medicina59101841. PMC 10607957. PMID 37893559.
8. Aggarwal A, Srivastava P (February 2015). "Childhood onset systemic lupus erythematosus: how is it different from adult SLE?". International Journal of Rheumatic Diseases. 18 (2): 182–91. doi:10.1111/1756-185X.12419. PMID 24965742.
9. Smith EM, Lythgoe H, Midgley A, Beresford MW, Hedrich CM (December 2019). "Juvenile-onset systemic lupus erythematosus: Update on clinical presentation, pathophysiology and treatment options". Clinical Immunology (Orlando, Fla.). 209: 108274. doi:10.1016/j.clim.2019.108274. PMID 31678365.
10. Watson L, Leone V, Pilkington C, Tullus K, Rangaraj S, McDonagh JE, Gardner-Medwin J, Wilkinson N, Riley P, Tizard J, Armon K, Sinha MD, Ioannou Y, Archer N, Bailey K, Davidson J, Baildam EM, Cleary G, McCann LJ, Beresford MW (July 2012). "Disease activity, severity, and damage in the UK Juvenile-Onset Systemic Lupus Erythematosus Cohort". Arthritis and Rheumatism. 64 (7): 2356–65. doi:10.1002/art.34410. PMID 22294381.
11. Sakamoto AP, Silva CA, Islabão AG, Novak GV, Molinari B, Nogueira PK, Pereira RM, Saad-Magalhães C, Clemente G, Piotto DP, Aikawa NE, Pitta AC, Trindade VC, Appenzeller S, Carvalho LM, Rabelo-Junior CN, Fonseca AR, Sztajnbok FR, Santos MC, Bica BE, Sena EG, Moraes AJ, Fraga MM, Robazzi TC, Spelling PF, Scheibel IM, Cavalcanti AS, Matos EN, Guimarães LJ, Santos FP, Mota LM, Bonfá E, Terreri MT (June 2023). "Chronic kidney disease in patients with childhood-onset systemic lupus erythematosus". Pediatric Nephrology (Berlin, Germany). 38 (6): 1843–1854. doi:10.1007/s00467-022-05811-y. PMID 36409367.
12. Miguel DF, Terreri MT, Pereira RM, Bonfá E, Silva CA, Corrente JE, Magalhaes CS (February 2020). "Comparison of urinary parameters, biomarkers, and outcome of childhood systemic lupus erythematosus early onset-lupus nephritis". Advances in Rheumatology (London, England). 60 (1): 10. doi:10.1186/s42358-020-0114-4. PMID 32005292.
13. Chang JC, Weiss PF, Xiao R, Atkinson MA, Wenderfer SE (August 2022). "Use of renin angiotensin aldosterone system inhibitors in children with lupus and time to glucocorticoid discontinuation". Kidney International. 102 (2): 395–404. doi:10.1016/j.kint.2022.04.023. PMC 9329244. PMID 35618096.
14. Ulloa AC, Liao F, Carlomagno RL, Diaz T, Dominguez D, Levy DM, Ng L, Knight AM, Hiraki LT (February 2022). "Schizophrenia Genetics and Neuropsychiatric Features in Childhood-onset Systemic Lupus Erythematosus". The Journal of Rheumatology. 49 (2): 192–196. doi:10.3899/jrheum.210363.
15. van der Heijden H, Rameh V, Golden E, Ronen I, Sundel RP, Knight A, Chang JC, Upadhyay J (March 2024). "Implications of Inflammatory Processes on a Developing Central Nervous System in Childhood-Onset Systemic Lupus Erythematosus". Arthritis & Rheumatology (Hoboken, N.J.). 76 (3): 332–344. doi:10.1002/art.42736. PMID 37901986.
16. Liu Y, Zhu J, Lai JM, Sun XF, Hou J, Zhou ZX, Yuan XY (January 2018). "Reports of three cases with the initial presentation of mesenteric vasculitis in children with system lupus erythematous". Clinical Rheumatology. 37 (1): 277–283. doi:10.1007/s10067-017-3841-0. PMID 29019060.
17. Huggins JL, Holland MJ, Brunner HI (July 2016). "Organ involvement other than lupus nephritis in childhood-onset systemic lupus erythematosus". Lupus. 25 (8): 857–63. doi:10.1177/0961203316644339. PMID 27252262.
18. Gormezano NW, Otsuzi CI, Barros DL, da Silva MA, Pereira RM, Campos LM, Borba EF, Bonfá E, Silva CA (June 2016). "Macrophage activation syndrome: A severe and frequent manifestation of acute pancreatitis in 362 childhood-onset compared to 1830 adult-onset systemic lupus erythematosus patients". Seminars in Arthritis and Rheumatism. 45 (6): 706–10. doi:10.1016/j.semarthrit.2015.10.015. PMID 26833399.
19. AlE'ed A, Aydin PO, Al Mutairi N, AlSaleem A, Sonmez HE, Henrickson M, Huggins JL, Ozen S, Al-Mayouf SM, Brunner HI (2018). "Validation of the Cutaneous Lupus Erythematosus Disease Area and Severity Index and pSkindex27 for use in childhood-onset systemic lupus erythematosus". Lupus Science & Medicine. 5 (1): e000275. doi:10.1136/lupus-2018-000275. PMC 6257379. PMID 30538816.
20. David C, Arango-Franco CA, Badonyi M, Fouchet J, Rice GI, Didry-Barca B, Maisonneuve L, Seabra L, Kechiche R, Masson C, Cobat A, Abel L, Talouarn E, Béziat V, Deswarte C, Livingstone K, Paul C, Malik G, Ross A, Adam J, Walsh J, Kumar S, Bonnet D, Bodemer C, Bader-Meunier B, Marsh JA, Casanova JL, Crow YJ, Manoury B, Frémond ML, Bohlen J, Lepelley A (August 2024). "Gain-of-function human UNC93B1 variants cause systemic lupus erythematosus and chilblain lupus". The Journal of Experimental Medicine. 221 (8). doi:10.1084/jem.20232066. PMC 11176256. PMID 38869500.
21. Ogbu EA, Chandrakasan S, Rouster-Stevens K, Greenbaum LA, Sanz I, Gillespie SE, Marion C, Okeson K, Prahalad S (January 2021). "Impact of autoimmune cytopenias on severity of childhood-onset systemic lupus erythematosus: A single-center retrospective cohort study". Lupus. 30 (1): 109–117. doi:10.1177/0961203320969806. PMC 7769889. PMID 33108953.
22. Benz K, Amann K (May 2010). "Thrombotic microangiopathy: new insights". Current Opinion in Nephrology and Hypertension. 19 (3): 242–7. doi:10.1097/MNH.0b013e3283378f25. PMID 20186056.
23. Wi D, Palermo TM, Stevens A, Ward TM (October 2024). "Sleep deficiency and symptoms of pain, fatigue, and depressed mood in youth with and without childhood systemic lupus erythematosus". Journal of Clinical Sleep Medicine : JCSM : Official Publication of the American Academy of Sleep Medicine. 20 (10): 1607–1614. doi:10.5664/jcsm.11210. PMID 38738616.
24. Arnaud L, Furie R, Morand EF, Aringer M, Peschken C, Desta B, Rapsomaniki E, Hedberg J, Knagenhjelm J, Seo C, Grünfeld Eén T, Sorrentino A, Tummala R, Stirnadel-Farrant HA, Ding B (December 2023). "Burden of systemic lupus erythematosus in clinical practice: baseline data from the SLE Prospective Observational Cohort Study (SPOCS) by interferon gene signature". Lupus Science & Medicine. 10 (2). doi:10.1136/lupus-2023-001032. PMC 10749026. PMID 38123459.
25. Malleson P, Petty RE, Nadel H, Dimmick JE (November 1988). "Functional asplenia in childhood onset systemic lupus erythematosus". The Journal of Rheumatology. 15 (11): 1648–52. PMID 3070028.
26. Kaya Akca U, Sener S, Batu ED, Balik Z, Basaran O, Bilginer Y, Ozen S (June 2024). "Drug-induced lupus erythematosus in childhood: Case-based review". Lupus. 33 (7): 737–748. doi:10.1177/09612033241245078. PMID 38580326.
27. Takei S, Igarashi T, Kubota T, Tanaka E, Yamaguchi K, Yamazaki K, Itoh Y, Arai S, Okamoto K, Mori M (February 2022). "Clinical practice guidance for childhood-onset systemic lupus erythematosus-secondary publication". Modern Rheumatology. 32 (2): 239–247. doi:10.1093/mr/roab002. PMID 34910196.
28. Demir S, Gülhan B, Özen S, Çeleğen K, Batu ED, Taş N, Orhan D, Bilginer Y, Düzova A, Ozaltin F, Topaloğlu R (May 2022). "Long-term renal survival of paediatric patients with lupus nephritis". Nephrology, Dialysis, Transplantation : Official Publication of the European Dialysis and Transplant Association - European Renal Association. 37 (6): 1069–1077. doi:10.1093/ndt/gfab152. PMID 33826705.
29. Fanouriakis A, Tziolos N, Bertsias G, Boumpas DT (January 2021). "Update οn the diagnosis and management of systemic lupus erythematosus". Annals of the Rheumatic Diseases. 80 (1): 14–25. doi:10.1136/annrheumdis-2020-218272. PMID 33051219.
30. Novak GV, Marques M, Balbi V, Gormezano NW, Kozu K, Sakamoto AP, Pereira RM, Terreri MT, Magalhães CS, Guariento A, Sallum AM, Marini R, Ferriani VP, Barbosa CM, de Castro TC, Ramos VC, Bonfá E, Silva CA (February 2017). "Anti-RO/SSA and anti-La/SSB antibodies: Association with mild lupus manifestations in 645 childhood-onset systemic lupus erythematosus". Autoimmunity Reviews. 16 (2): 132–135. doi:10.1016/j.autrev.2016.12.004. PMID 27988434.
31. Accapezzato D, Caccavale R, Paroli MP, Gioia C, Nguyen BL, Spadea L, Paroli M (March 2023). "Advances in the Pathogenesis and Treatment of Systemic Lupus Erythematosus". International Journal of Molecular Sciences. 24 (7). doi:10.3390/ijms24076578. PMC 10095030. PMID 37047548.
32. Tusseau M, Khaldi-Plassart S, Cognard J, Viel S, Khoryati L, Benezech S, Mathieu AL, Rieux-Laucat F, Bader-Meunier B, Belot A (April 2024). "Mendelian Causes of Autoimmunity: the Lupus Phenotype". Journal of Clinical Immunology. 44 (4): 99. doi:10.1007/s10875-024-01696-8. PMID 38619739.
33. An J, Marwaha A, Laxer RM (September 2024). "Autoinflammatory Diseases: A Review". The Journal of Rheumatology. 51 (9): 848–861. doi:10.3899/jrheum.2023-1209. PMID 38879186.
34. Wu CY, Fan WL, Yang HY, Chu PS, Liao PC, Chen LC, Yao TC, Yeh KW, Ou LS, Lin SJ, Lee WI, Huang JL (April 2023). "Contribution of genetic variants associated with primary immunodeficiencies to childhood-onset systemic lupus erythematous". The Journal of Allergy and Clinical Immunology. 151 (4): 1123–1131. doi:10.1016/j.jaci.2022.12.807. PMID 36586539.
35. Bousfiha A, Moundir A, Tangye SG, Picard C, Jeddane L, Al-Herz W, Rundles CC, Franco JL, Holland SM, Klein C, Morio T, Oksenhendler E, Puel A, Puck J, Seppänen MR, Somech R, Su HC, Sullivan KE, Torgerson TR, Meyts I (October 2022). "The 2022 Update of IUIS Phenotypical Classification for Human Inborn Errors of Immunity". Journal of Clinical Immunology. 42 (7): 1508–1520. doi:10.1007/s10875-022-01352-z. PMID 36198931.
36. Yu JE (February 2024). "New primary immunodeficiencies 2023 update". Current Opinion in Pediatrics. 36 (1): 112–123. doi:10.1097/MOP.0000000000001315. PMID 38001560.
37. Wolf C, Lim EL, Mokhtari M, Kind B, Odainic A, Lara-Villacanas E, Koss S, Mages S, Menzel K, Engel K, Dückers G, Bernbeck B, Schneider DT, Siepermann K, Niehues T, Goetzke CC, Durek P, Minden K, Dörner T, Stittrich A, Szelinski F, Guerra GM, Massoud M, Bieringer M, de Oliveira Mann CC, Beltrán E, Kallinich T, Mashreghi MF, Schmidt SV, Latz E, Klughammer J, Majer O, Lee-Kirsch MA (February 2024). "UNC93B1 variants underlie TLR7-dependent autoimmunity". Science Immunology. 9 (92): eadi9769. doi:10.1126/sciimmunol.adi9769. PMID 38207055.
38. Al-Azab M, Idiiatullina E, Liu Z, Lin M, Hrovat-Schaale K, Xian H, Zhu J, Yang M, Lu B, Zhao Z, Liu Y, Chang J, Li X, Guo C, Liu Y, Wu Q, Chen J, Lan C, Zeng P, Cui J, Gao X, Zhou W, Zhang Y, Zhang Y, Masters SL (June 2024). "Genetic variants in UNC93B1 predispose to childhood-onset systemic lupus erythematosus". Nature Immunology. 25 (6): 969–980. doi:10.1038/s41590-024-01846-5. PMC 11147776. PMID 38831104.
39. Pereira KM, Perazzio S, Faria AG, Moreira ES, Santos VC, Grecco M, da Silva NP, Andrade LE (August 2019). "Impact of C4, C4A and C4B gene copy number variation in the susceptibility, phenotype and progression of systemic lupus erythematosus". Advances in Rheumatology (London, England). 59 (1): 36. doi:10.1186/s42358-019-0076-6. PMID 31387635.
40. Marin WM, Augusto DG, Wade KJ, Hollenbach JA (January 2024). "High-throughput complement component 4 genomic sequence analysis with C4Investigator". HLA. 103 (1): e15273. doi:10.1111/tan.15273. PMC 11099535. PMID 37899688.
41. Yang W, Ng P, Zhao M, Hirankarn N, Lau CS, Mok CC, Chan TM, Wong RW, Lee KW, Mok MY, Wong SN, Avihingsanon Y, Lee TL, Ho MH, Lee PP, Wong WH, Lau YL (April 2009). "Population differences in SLE susceptibility genes: STAT4 and BLK, but not PXK, are associated with systemic lupus erythematosus in Hong Kong Chinese". Genes and Immunity. 10 (3): 219–26. doi:10.1038/gene.2009.1. PMID 19225526.
42. Kousi M, Katsanis N (June 2015). "Genetic modifiers and oligogenic inheritance". Cold Spring Harbor Perspectives in Medicine. 5 (6): a017145. doi:10.1101/cshperspect.a017145. PMC 4448705. PMID 26033081.
43. Crouch DJ, Bodmer WF (August 2020). "Polygenic inheritance, GWAS, polygenic risk scores, and the search for functional variants". Proceedings of the National Academy of Sciences of the United States of America. 117 (32): 18924–18933. Bibcode:2020PNAS..11718924C. doi:10.1073/pnas.2005634117. PMC 7431089. PMID 32753378.
44. Arnaud L, Mertz P, Gavand PE, Martin T, Chasset F, Tebacher-Alt M, Lambert A, Muller C, Sibilia J, Lebrun-Vignes B, Salem JE (April 2019). "Drug-induced systemic lupus: revisiting the ever-changing spectrum of the disease using the WHO pharmacovigilance database". Annals of the Rheumatic Diseases. 78 (4): 504–508. doi:10.1136/annrheumdis-2018-214598. PMID 30793701.
45. Schneider L, Dos Santos AS, Santos M, da Silva Chakr RM, Monticielo OA (August 2014). "Vitamin D and systemic lupus erythematosus: state of the art". Clinical Rheumatology. 33 (8): 1033–1038. doi:10.1007/s10067-014-2530-5. PMID 24573738. S2CID 28033436.
46. Athanassiou L, Kostoglou-Athanassiou I, Koutsilieris M, Shoenfeld Y (April 2023). "Vitamin D and Autoimmune Rheumatic Diseases". Biomolecules. 13 (4): 709. doi:10.3390/biom13040709. PMC 10135889. PMID 37189455.
47. Irfan SA, Ali AA, Shabbir N, Altaf H, Ahmed A, Thamara Kunnath J, Divya Boorle NV, Miguel AK, Loh CC, Gandrakota N, Ali Baig MM (June 2022). "Effects of Vitamin D on Systemic Lupus Erythematosus Disease Activity and Autoimmunity: A Systematic Review and Meta-Analysis". Cureus. 14 (6): e25896. doi:10.7759/cureus.25896. PMC 9278795. PMID 35844337.
48. Ho LJ, Wu CH, Luo SF, Lai JH (September 2024). "Vitamin D and systemic lupus erythematosus: Causality and association with disease activity and therapeutics". Biochemical Pharmacology. 227: 116417. doi:10.1016/j.bcp.2024.116417. PMID 38996931.
49. Jiao H, Acar G, Robinson GA, Ciurtin C, Jury EC, Kalea AZ (September 2022). "Diet and Systemic Lupus Erythematosus (SLE): From Supplementation to Intervention". International Journal of Environmental Research and Public Health. 19 (19). doi:10.3390/ijerph191911895. PMC 9565311. PMID 36231195.
50. Cheng KH, Tsai MC, Fu LS (May 2022). "The correlation between VitD3 levels and the disease activity of childhood-onset systemic lupus erythematosus". Journal of the Chinese Medical Association : JCMA. 85 (5): 627–632. doi:10.1097/JCMA.0000000000000702. PMID 35506950.
51. Chauss D, Freiwald T, McGregor R, Yan B, Wang L, Nova-Lamperti E, Kumar D, Zhang Z, Teague H, West EE, Vannella KM, Ramos-Benitez MJ, Bibby J, Kelly A, Malik A, Freeman AF, Schwartz DM, Portilla D, Chertow DS, John S, Lavender P, Kemper C, Lombardi G, Mehta NN, Cooper N, Lionakis MS, Laurence A, Kazemian M, Afzali B (January 2022). "Autocrine vitamin D signaling switches off pro-inflammatory programs of TH1 cells". Nature Immunology. 23 (1): 62–74. doi:10.1038/s41590-021-01080-3. PMID 34764490.
52. Lebiedziński F, Lisowska KA (July 2023). "Impact of Vitamin D on Immunopathology of Hashimoto's Thyroiditis: From Theory to Practice". Nutrients. 15 (14). doi:10.3390/nu15143174. PMID 37513592.
53. Horai Y, Shimizu T, Umeda M, Nishihata SY, Nakamura H, Kawakami A (September 2023). "Current Views on Pathophysiology and Potential Therapeutic Targets in Sjögren's Syndrome: A Review from the Perspective of Viral Infections, Toll-like Receptors, and Long-Noncoding RNAs". Journal of Clinical Medicine. 12 (18). doi:10.3390/jcm12185873. PMC 10531551. PMID 37762814.
54. Fonseca AR, Gaspar-Elsas MI, Land MG, de Oliveira SK (February 2015). "Comparison between three systems of classification criteria in juvenile systemic lupus erythematous". Rheumatology (Oxford, England). 54 (2): 241–7. doi:10.1093/rheumatology/keu278. PMID 25125590.
55. Petri M, Orbai AM, Alarcón GS, Gordon C, Merrill JT, Fortin PR, Bruce IN, Isenberg D, Wallace DJ, Nived O, Sturfelt G, Ramsey-Goldman R, Bae SC, Hanly JG, Sánchez-Guerrero J, Clarke A, Aranow C, Manzi S, Urowitz M, Gladman D, Kalunian K, Costner M, Werth VP, Zoma A, Bernatsky S, Ruiz-Irastorza G, Khamashta MA, Jacobsen S, Buyon JP, Maddison P, Dooley MA, van Vollenhoven RF, Ginzler E, Stoll T, Peschken C, Jorizzo JL, Callen JP, Lim SS, Fessler BJ, Inanc M, Kamen DL, Rahman A, Steinsson K, Franks AG, Sigler L, Hameed S, Fang H, Pham N, Brey R, Weisman MH, McGwin G, Magder LS (August 2012). "Derivation and validation of the Systemic Lupus International Collaborating Clinics classification criteria for systemic lupus erythematosus". Arthritis and Rheumatism. 64 (8): 2677–86. doi:10.1002/art.34473. PMC 3409311. PMID 22553077.
56. Aljaberi N, Nguyen K, Strahle C, Merritt A, Mathur A, Brunner HI (April 2021). "Performance of the New 2019 European League Against Rheumatism/American College of Rheumatology Classification Criteria for Systemic Lupus Erythematosus in Children and Young Adults". Arthritis Care & Research. 73 (4): 580–585. doi:10.1002/acr.24430. PMID 32841547.
57. von Mühlen CA, Garcia-De La Torre I, Infantino M, Damoiseaux J, Andrade LE, Carballo OG, Conrad K, Francescantonio PL, Fritzler MJ, Herold M, Klotz W, de Melo Cruvinel W, Mimori T, Satoh M, Musset L, Chan EK (December 2021). "How to report the antinuclear antibodies (anti-cell antibodies) test on HEp-2 cells: guidelines from the ICAP initiative". Immunologic Research. 69 (6): 594–608. doi:10.1007/s12026-021-09233-0. PMID 34625914.
58. Lima GL, Paupitz J, Aikawa NE, Takayama L, Bonfa E, Pereira RM (January 2016). "Vitamin D Supplementation in Adolescents and Young Adults With Juvenile Systemic Lupus Erythematosus for Improvement in Disease Activity and Fatigue Scores: A Randomized, Double-Blind, Placebo-Controlled Trial". Arthritis Care & Research. 68 (1): 91–8. doi:10.1002/acr.22621. PMID 25988278.
59. Mai L, Asaduzzaman A, Noamani B, Fortin PR, Gladman DD, Touma Z, Urowitz MB, Wither J (January 2021). "The baseline interferon signature predicts disease severity over the subsequent 5 years in systemic lupus erythematosus". Arthritis Research & Therapy. 23 (1): 29. doi:10.1186/s13075-021-02414-0. PMC 7811214. PMID 33451338.
60. Trindade VC, Carneiro-Sampaio M, Bonfa E, Silva CA (July 2021). "An Update on the Management of Childhood-Onset Systemic Lupus Erythematosus". Paediatric Drugs. 23 (4): 331–347. doi:10.1007/s40272-021-00457-z. PMC 8270778. PMID 34244988.
61. Avar-Aydın PÖ, I Brunner H (July 2024). "Revisiting Childhood-Onset Systemic Lupus Erythematosus". Turkish Archives of Pediatrics. 59 (4): 336–344. doi:10.5152/TurkArchPediatr.2024.24097. PMC 11332533. PMID 39102578.
62. Gladman DD, Ibañez D, Urowitz MB (February 2002). "Systemic lupus erythematosus disease activity index 2000". The Journal of Rheumatology. 29 (2): 288–91. PMID 11838846.
63. Elshaer R, Jaber S, Odeh N, Arbili L, Al-Mayouf SM (March 2024). "Safety and efficacy of biologics in childhood systemic lupus erythematosus: a critical systematic review". Clinical Rheumatology. 43 (3): 863–877. doi:10.1007/s10067-023-06833-z. PMID 38079010.
64. Deng J, Chalhoub NE, Sherwin CM, Li C, Brunner HI (October 2019). "Glucocorticoids pharmacology and their application in the treatment of childhood-onset systemic lupus erythematosus". Seminars in Arthritis and Rheumatism. 49 (2): 251–259. doi:10.1016/j.semarthrit.2019.03.010. PMC 6744986. PMID 30987856.
65. Pan L, Liu J, Liu C, Guo L, Punaro M, Yang S (2023). "Childhood-onset systemic lupus erythematosus: characteristics and the prospect of glucocorticoid pulse therapy". Frontiers in Immunology. 14: 1128754. doi:10.3389/fimmu.2023.1128754. PMC 10448525. PMID 37638017.
66. Carreño L, López-Longo FJ, González CM, Monteagudo I (2002). "Treatment options for juvenile-onset systemic lupus erythematosus". Paediatric Drugs. 4 (4): 241–56. doi:10.2165/00128072-200204040-00004. PMID 11960513.
67. Muanda FT, Blake PG, Weir MA, Ahmadi F, McArthur E, Sontrop JM, Urquhart BL, Kim RB, Garg AX (November 2023). "Low-Dose Methotrexate and Serious Adverse Events Among Older Adults With Chronic Kidney Disease". JAMA Network Open. 6 (11): e2345132. doi:10.1001/jamanetworkopen.2023.45132. PMC 10682837. PMID 38010652.
68. Barroso A, Estevinho F, Hespanhol V, Teixeira E, Ramalho-Carvalho J, Araújo A (March 2024). "Management of infusion-related reactions in cancer therapy: strategies and challenges". ESMO Open. 9 (3): 102922. doi:10.1016/j.esmoop.2024.102922. PMC 10937241. PMID 38452439. {{cite journal}}: no-break space character in |title= at position 75 (help)
69. Mok CC (June 2017). "Calcineurin inhibitors in systemic lupus erythematosus". Best Practice & Research. Clinical Rheumatology. 31 (3): 429–438. doi:10.1016/j.berh.2017.09.010. PMID 29224682.
70. Cite error: The named reference pmid3561809 was invoked but never defined (see the help page).
71. Modica RF, Thatayatikom A, Bell-Brunson DH, Elder ME (July 2023). "Bortezomib is efficacious in the treatment of severe childhood-onset neuropsychiatric systemic lupus erythematosus with psychosis: a case series and mini-review of B-cell immunomodulation in antibody-mediated diseases". Clinical Rheumatology. 42 (7): 1965–1979. doi:10.1007/s10067-023-06559-y. PMID 36971919.
72. de Zubiria Salgado A, Herrera-Diaz C (2012). "Lupus nephritis: an overview of recent findings". Autoimmune Diseases. 2012: 849684. doi:10.1155/2012/849684. PMC 3318208. PMID 22536486.
73. Tucker LB, Uribe AG, Fernández M, Vilá LM, McGwin G, Apte M, Fessler BJ, Bastian HM, Reveille JD, Alarcón GS (April 2008). "Adolescent onset of lupus results in more aggressive disease and worse outcomes: results of a nested matched case-control study within LUMINA, a multiethnic US cohort (LUMINA LVII)". Lupus. 17 (4): 314–22. doi:10.1177/0961203307087875. PMC 2818044. PMID 18413413.
74. Ambrose N, Morgan TA, Galloway J, Ionnoau Y, Beresford MW, Isenberg DA (December 2016). "Differences in disease phenotype and severity in SLE across age groups". Lupus. 25 (14): 1542–1550. doi:10.1177/0961203316644333. PMC 5089221. PMID 27147622.
75. Bennett M, Brunner HI (November 2013). "Biomarkers and updates on pediatrics lupus nephritis". Rheumatic Diseases Clinics of North America. 39 (4): 833–53. doi:10.1016/j.rdc.2013.05.001. PMC 4980821. PMID 24182857.