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User:Dr3939/翻译史 [3] 摘要 - 色素沉着绒毛结节性滑膜炎 费尔蒂症候群 单克隆抗体治疗 自体免疫

  1. 古塞奇尤单抗, 瑞沙珠单抗, 罗莫珠单抗, 阿伏利尤单抗 - 2024/11/05, 摘要
  2. 司库奇尤单抗, 伊班膦酸, 来氟米特 - 2024/11/04, 摘要
  3. 乌帕替尼, 阿巴西普, 类A酸, 冷冻沉淀品, 舒林酸 - 2024/11/03, 摘要
  4. 绒毛羊膜炎 - 2024/11/02, 摘要
  5. 抗NMDA受体脑炎, Template:肿瘤伴随症候群 - 2024/11/02, 摘要; 范本, 全
  6. 妊娠多形疹 - 2024/11/02, 摘要
  7. 肾上腺功能不全 - 2024/11/01, 摘要
  8. 复杂性局部疼痛症候群 - 2024/11/01, 摘要
  9. 暂时性滑膜炎 - 2024/11/01, 摘要
  10. 药物疹合并嗜伊红血症及全身症状 - 2024/10/31, 摘要
  11. 脂肪乳 - 2024/10/31, 摘要
  12. 鹰嘴突滑囊炎 - 2024/10/31, 摘要
  13. 血小板减少症 - 2024/10/31, 摘要
  14. 髌骨肌腱炎 - 2024/10/31, 摘要
  15. 结节性红斑 - 2024/10/31, 摘要
  16. 坏疽性脓皮症 - 2024/10/31, 摘要
  17. 心包积液 - 2024/10/31, 摘要
  18. 髌前滑囊炎 - 2024/10/30, 摘要
  19. 静脉炎 - 2024/10/30, 摘要
  20. 氢羟肾上腺皮质素 - 2024/10/30, 摘要 / 更新
  21. 硫酸锌 (药品) - 2024/10/30, 摘要
  22. 那曲酮 - 2024/10/30, 摘要
  23. 磺达肝癸钠 - 2024/10/30, 摘要
  24. 风湿性多肌痛症 - 2024/10/29, 摘要
  25. 肋软骨炎 - 2024/10/28, 摘要
  26. 掌腱膜挛缩症 - 2024/10/27, 摘要
  27. 药物不良反应 - 2024/01/14, 全
  28. NUDT15 - 2023/12/24, 全
  29. 前景问题格式, 证据等级, Category:实证应用‎, Template:实证应用, Template:实证医学应用 - 2022/4/24-5/08, WikiMed X TEBMA, 全, 编修+审查
  30. 二水合焦磷酸钙晶体沉积病 - 2021/12/06-12/08, 全
  31. Template:骨软骨病 - 2021/11/28, 范本, 全-更新
  32. 羟氯喹 - 2020/04/12, 医周译小时, 摘要
  33. 磺胺嘧啶, 结节病, Template:Sarcoidosis - 2020/04/04, 医周译小时, 全-摘要-范本
  34. 自体免疫, 软组织疾病, 黄房子 (梵高) - 2020/01/27, 长条目, 摘要/全/扩充
  35. 风湿, 单克隆抗体治疗, 单克隆抗体治疗 - 2020/01/26, 长条目, 全/摘要.
  36. Template:儿童关节炎 - 2020/01/23, 范本, 全;锌缺乏 - 2020/01/23, 审查
  37. 幼年特发性关节炎 - 2020/01/15, 长条目, 全
  38. Template:滑液检查‎ - 2020/01/12, 范本, 全
  39. 败血性关节炎‎ - 2020/01/08, 长条目, 全
  40. Template:骨软骨病 - 2020/1/6, 范本, 全
  41. v 反复性风湿症 - 2020/1/3, 小作品级, 全
  42. 骨赘, 骨质增生 - 2020/1/1, 小作品级, 全
  43. 反应性关节炎, 莱特氏症候群 - 2019/12/22, 长条目, 全
  44. v 成人史迪尔氏病, 成人史迪尔氏症候群 - 2019/12/21, 长条目, 全
  45. 关节痛 - 2019/12/19, 长条目, 全
  46. 骨头侵蚀, 骨侵蚀 - 2019/12/18, 长条目, 全
  47. 寡关节炎 - 2019/12/10, 长条目, 全
  48. 爱迪生氏病, 恶性贫血 - 2019/12/04, 医周译小时
  49. 著骨点炎, 接骨点炎, 附着部炎, 著骨点病变, 接骨点病变, 附着部病变 - 2019/11/18, 长条目, 全
  50. 脊椎炎, 脊椎病变, 荐肠关节炎, 椎间盘炎, 脊椎椎间盘炎, 博特氏病 - 2019/11/17, 长条目, 全
  51. 关节僵硬, 关节积血, 绒毛结节性滑膜炎, 色素沉着绒毛结节性滑膜炎 (摘要), Category:风湿病学, v 风湿病学 - 2019/11/16, 长条目, 全
  52. v 希伯登氏结节, 布夏氏结节 - 2019/11/15, 小作品级, 全
  53. 单关节炎, 多关节炎, 费尔蒂症候群, 结晶性关节病变, 软骨钙质沉积病 - 2019/11/13, 小作品级, 全
  54. SpA, 脊椎关节炎, 血清阴性脊椎关节病变, SPA (消歧义), v 干癣性关节炎 - 2019/11/12, 转址 - 扩充 - 长条目, 全
  55. 关节病变, 脊椎关节病变 - 2019/11/11, 小作品级, 全
  56. Template:过敏及自体免疫疾病, Template:全身性结缔组织疾病, Template:全身性血管炎, Template:过敏状况 - 2019/11/10, 范本, 全
  57. Template:自体抗原 - 2019/11/09, 范本, 全
  58. Template:关节病变和相关疾病, Template:脊椎疾病 - 2019/11/08, 范本, 全
  59. v 反复流产 - 2019/10/29-11/03 , 长条目, 全
  60. v 流产 - 2019/10/19-10/29, 长条目, 全, 补充 及 更新;
  61. 失智症 - 2019/10/13, 长条目, 部分, 医周译小时;
  62. v 类风湿因子, Template:自体抗体 - 2019/10/08-10/10 长条目/范本, 全
  63. v 抗甲状腺自体抗体 - 2019/10/07-10/09, 长条目, 部分 及 整合
  64. 结节性甲状腺肿 - 2019/10/08, 消歧义, 全
  65. Category:脚部疾病‎, Category:过度使用伤害‎, Category:软组织疾病‎‎, Template:软组织疾病 2019/09/27, 类别/范本, 全 及 补充
  66. v 足底筋膜炎 - 2019/09/10~9/20, 长条目, 部分, 医周译小时; 9/21-22 整合
  67. v 女性不孕症 - 2019/09/09~10/04, 长条目, 部分
  68. v 不孕 - 2019/09/04~9/07, 长条目, 部分
  69. 生酮饮食 Draft:生酮饮食 - 2019/08/20~9/03, 长条目, 部分
  70. 拉米夫定 - 2019/08/19, 医周译小时
  71. 肝豆状核变性, 三环类抗抑郁药药物过量 - 2019/08/16, 医周译小时
  72. v 实证医学 - 2019/08/11~8/20, 长条目, 全

开始:实证医学


  • 首次建立账号 2005年3月22日 (二) 14:01‎

重叠症候群英语Overlap syndrome 抗环瓜氨酸肽抗体英语Anti-citrullinated protein antibody 外生骨赘英语exostosis en:Exostosis en:Template:Osteochondropathy 模板:骨软骨病 著骨点增生英语enthesophyte en:Inflammatory arthritis


全身发作型幼年特发性关节炎

en:Systemic-onset juvenile idiopathic arthritis 全身发作型幼年特发性关节炎英语Systemic-onset juvenile idiopathic arthritis 儿童关节炎英语childhood arthritis

自体免疫

自体免疫

自体免疫

免疫耐受性

  • 株落忽视理论指出在胸腺中未显现自身反应性的 T 细胞将成熟并迁移到周边组织,在周边组织内,T 细胞无法接近的组织,所以不会遇到合适的抗原。因此,逃脱株落删除的自身反应性 B 细胞无法找到抗原或特定的辅助性T细胞来活化它们。[1]
  • 抑制群体调节T细胞理论:调节性 T 淋巴细胞(通常为 CD4+FoxP3+ 细胞)的工作在于预防、下调或限制免疫系统中的自身反应性被激活。

Tolerance can also be differentiated into "central" and "peripheral" tolerance, on whether or not the above-stated checking mechanisms operate in the central lymphoid organs (thymus and bone marrow) or the peripheral lymphoid organs (lymph node, spleen, etc., where self-reactive B-cells may be destroyed). It must be emphasised that these theories are not mutually exclusive, and evidence has been mounting suggesting that all of these mechanisms may actively contribute to vertebrate immunological tolerance.

关于上述检查机制是在中央淋巴器官(胸腺和骨髓)还是在外周淋巴器官(淋巴结,脾脏等)中起作用,耐受性还可以分为“中心”耐受性和“外周”耐受性。 ,其中自反应性B细胞可能会被破坏)。 必须强调的是,这些理论并不是相互排斥的,并且越来越多的证据表明所有这些机制都可能积极地促进脊椎动物的免疫耐受。

A puzzling feature of the documented loss of tolerance seen in spontaneous human autoimmunity is that it is almost entirely restricted to the autoantibody responses produced by B lymphocytes. Loss of tolerance by T cells has been extremely hard to demonstrate, and where there is evidence for an abnormal T cell response it is usually not to the antigen recognised by autoantibodies. Thus, in rheumatoid arthritis there are autoantibodies to IgG Fc but apparently no corresponding T cell response. In systemic lupus there are autoantibodies to DNA, which cannot evoke a T cell response, and limited evidence for T cell responses implicates nucleoprotein antigens. In Celiac disease there are autoantibodies to tissue transglutaminase but the T cell response is to the foreign protein gliadin. This disparity has led to the idea that human autoimmune disease is in most cases (with probable exceptions including type I diabetes) based on a loss of B cell tolerance which makes use of normal T cell responses to foreign antigens in a variety of aberrant ways.[2]   

自发性人类自体免疫中所见的耐受性丧失的一个令人困惑的特征是,它几乎完全限于B淋巴细胞产生的自身抗体反应。很难证明T细胞丧失了耐受性,并且在有证据表明存在异常的T细胞反应的情况下,通常不是针对自身抗体识别的抗原。因此,在类风湿关节炎中,存在针对IgG Fc的自身抗体,但显然没有相应的T细胞应答。在系统性狼疮中,有针对DNA的自身抗体,无法引起T细胞反应,而有关T细胞反应的证据有限,这牵涉到核蛋白抗原。在乳糜泻中,存在针对组织转谷氨酰胺酶的自身抗体,但T细胞对外源蛋白麦醇溶蛋白的反应。这种差异导致了这样一种观念,即人类自体免疫性疾病在大多数情况下(可能包括I型糖尿病)(基于B细胞耐受力丧失)是基于B细胞耐受性丧失的原因,而B细胞以各种异常方式利用了正常T细胞对外源抗原的反应。

Immunodeficiency and autoimmunity

There are a large number of immunodeficiency syndromes that present clinical and laboratory characteristics of autoimmunity. The decreased ability of the immune system to clear infections in these patients may be responsible for causing autoimmunity through perpetual immune system activation.[3]

One example is common variable immunodeficiency英语common variable immunodeficiency (CVID) where multiple autoimmune diseases are seen, e.g.: inflammatory bowel disease, autoimmune thrombocytopenia and autoimmune thyroid disease.

Familial hemophagocytic lymphohistiocytosis, an autosomal recessive primary immunodeficiency, is another example. Pancytopenia英语Pancytopenia, rashes, swollen lymph nodes英语lymphadenopathy and enlargement of the liver and spleen英语hepatosplenomegaly are commonly seen in such individuals. Presence of multiple uncleared viral infections due to lack of perforin are thought to be responsible.

In addition to chronic and/or recurrent infections many autoimmune diseases including arthritis, autoimmune hemolytic anemia, scleroderma and type 1 diabetes mellitus are also seen in X-linked agammaglobulinemia英语X-linked agammaglobulinemia (XLA). Recurrent bacterial and fungal infections and chronic inflammation of the gut and lungs are seen in chronic granulomatous disease (CGD) as well. CGD is a caused by decreased production of nicotinamide adenine dinucleotide phosphate (NADPH) oxidase by neutrophils. Hypomorphic RAG mutations are seen in patients with midline granulomatous disease; an autoimmune disorder that is commonly seen in patients with granulomatosis with polyangiitis and NK/T cell lymphomas.

Wiskott–Aldrich syndrome英语Wiskott–Aldrich syndrome (WAS) patients also present with eczema, autoimmune manifestations, recurrent bacterial infections and lymphoma.

In autoimmune polyendocrinopathy-candidiasis-ectodermal dystrophy英语autoimmune polyendocrinopathy-candidiasis-ectodermal dystrophy (APECED) also autoimmunity and infections coexist: organ-specific autoimmune manifestations (e.g. hypoparathyroidism and adrenocortical failure) and chronic mucocutaneous candidiasis.

Finally, IgA deficiency英语IgA deficiency is also sometimes associated with the development of autoimmune and atopic phenomena.

Genetic factors

Certain individuals are genetically susceptible to developing autoimmune diseases. This susceptibility is associated with multiple genes plus other risk factors. Genetically predisposed individuals do not always develop autoimmune diseases.

Three main sets of genes are suspected in many autoimmune diseases. These genes are related to:

The first two, which are involved in the recognition of antigens, are inherently variable and susceptible to recombination. These variations enable the immune system to respond to a very wide variety of invaders, but may also give rise to lymphocytes capable of self-reactivity.

Fewer correlations exist with MHC class I molecules. The most notable and consistent is the association between HLA B27 and spondyloarthropathies like ankylosing spondylitis and reactive arthritis. Correlations may exist between polymorphisms within class II MHC promoters and autoimmune disease.

The contributions of genes outside the MHC complex remain the subject of research, in animal models of disease (Linda Wicker's extensive genetic studies of diabetes in the NOD mouse), and in patients (Brian Kotzin's linkage analysis of susceptibility to SLE).

Recently, PTPN22英语PTPN22 has been associated with multiple autoimmune diseases including Type I diabetes, rheumatoid arthritis, systemic lupus erythematosus, Hashimoto’s thyroiditis, Graves’ disease, Addison’s disease, Myasthenia Gravis, vitiligo, systemic sclerosis juvenile idiopathic arthritis, and psoriatic arthritis.[5][需要解释]

Sex

Ratio of female/male incidence
of autoimmune diseases
Hashimoto's thyroiditis 10:1[6]
Graves' disease 7:1[6]
Multiple sclerosis (MS) 2:1[6]
Myasthenia gravis 2:1[6]
Systemic lupus erythematosus (SLE) 9:1[6]
Rheumatoid arthritis 5:2[6]
Primary sclerosing cholangitis 1:2

There is some evidence that a person's sex may also have some role in the development of autoimmunity; that is, most autoimmune diseases are sex-related英语sex-related diseases. A few autoimmune diseases that men are just as or more likely to develop as women include: ankylosing spondylitis, type 1 diabetes mellitus, granulomatosis with polyangiitis, Crohn's disease, Primary sclerosing cholangitis and psoriasis.

The reasons for the sex role in autoimmunity vary. Women appear to generally mount larger inflammatory responses than men when their immune systems are triggered, increasing the risk of autoimmunity. Involvement of sex steroids is indicated by that many autoimmune diseases tend to fluctuate in accordance with hormonal changes, for example: during pregnancy, in the menstrual cycle, or when using oral contraception. A history of pregnancy also appears to leave a persistent increased risk for autoimmune disease. It has been suggested that the slight, direct exchange of cells between mothers and their children during pregnancy may induce autoimmunity.[7] This would tip the gender balance in the direction of the female.

Another theory suggests the female high tendency to get autoimmunity is due to an imbalanced X-chromosome inactivation.[8] The X-inactivation skew theory, proposed by Princeton University's Jeff Stewart, has recently been confirmed experimentally in scleroderma and autoimmune thyroiditis.[9] Other complex X-linked genetic susceptibility mechanisms are proposed and under investigation.

Environmental factors

Infectious diseases and parasites

An interesting inverse relationship exists between infectious diseases and autoimmune diseases. In areas where multiple infectious diseases are endemic, autoimmune diseases are quite rarely seen. The reverse, to some extent, seems to hold true. The hygiene hypothesis attributes these correlations to the immune-manipulating strategies of pathogens. While such an observation has been variously termed as spurious and ineffective, according to some studies, parasite infection is associated with reduced activity of autoimmune disease.[10][11][12]

The putative mechanism is that the parasite attenuates the host immune response in order to protect itself. This may provide a serendipitous benefit to a host that also suffers from autoimmune disease. The details of parasite immune modulation are not yet known, but may include secretion of anti-inflammatory agents or interference with the host immune signaling.

A paradoxical observation has been the strong association of certain microbial organisms with autoimmune diseases. For example, Klebsiella pneumoniae and coxsackievirus B英语Coxsackie B have been strongly correlated with ankylosing spondylitis and diabetes mellitus type 1, respectively. This has been explained by the tendency of the infecting organism to produce super-antigens that are capable of polyclonal activation of B-lymphocytes, and production of large amounts of antibodies of varying specificities, some of which may be self-reactive (see below).

Chemical agents and drugs

Certain chemical agents and drugs can also be associated with the genesis of autoimmune conditions, or conditions that simulate autoimmune diseases. The most striking of these is the drug-induced lupus erythematosus英语drug-induced lupus erythematosus. Usually, withdrawal of the offending drug cures the symptoms in a patient.

Cigarette smoking is now established as a major risk factor for both incidence and severity of rheumatoid arthritis. This may relate to abnormal citrullination英语citrullination of proteins, since the effects of smoking correlate with the presence of antibodies to citrullinated peptides.

Pathogenesis of autoimmunity

Several mechanisms are thought to be operative in the pathogenesis of autoimmune diseases, against a backdrop of genetic predisposition and environmental modulation. It is beyond the scope of this article to discuss each of these mechanisms exhaustively, but a summary of some of the important mechanisms have been described:

  • T-cell bypass – A normal immune system requires the activation of B cells by T cells before the former can undergo differentiation into plasma B-cells and subsequently produce antibodies in large quantities. This requirement of a T cell can be bypassed in rare instances, such as infection by organisms producing super-antigens, which are capable of initiating polyclonal activation of B-cells, or even of T-cells, by directly binding to the β-subunit of T-cell receptors in a non-specific fashion.
  • T-cell–B-cell discordance – A normal immune response is assumed to involve B and T cell responses to the same antigen, even if we know that B cells and T cells recognise very different things: conformations on the surface of a molecule for B cells and pre-processed peptide fragments of proteins for T cells. However, there is nothing as far as we know that requires this. All that is required is that a B cell recognising antigen X endocytoses and processes a protein Y (normally =X) and presents it to a T cell. Roosnek and Lanzavecchia showed that B cells recognising IgGFc could get help from any T cell responding to an antigen co-endocytosed with IgG by the B cell as part of an immune complex. In coeliac disease it seems likely that B cells recognising tissue transglutamine are helped by T cells recognising gliadin.
  • Aberrant B cell receptor-mediated feedback – A feature of human autoimmune disease is that it is largely restricted to a small group of antigens, several of which have known signaling roles in the immune response (DNA, C1q, IgGFc, Ro, Con. A receptor, Peanut agglutinin receptor(PNAR)). This fact gave rise to the idea that spontaneous autoimmunity may result when the binding of antibody to certain antigens leads to aberrant signals being fed back to parent B cells through membrane bound ligands. These ligands include B cell receptor (for antigen), IgG Fc receptors, CD21, which binds complement C3d, Toll-like receptors 9 and 7 (which can bind DNA and nucleoproteins) and PNAR. More indirect aberrant activation of B cells can also be envisaged with autoantibodies to acetyl choline receptor (on thymic myoid cells) and hormone and hormone binding proteins. Together with the concept of T-cell–B-cell discordance this idea forms the basis of the hypothesis of self-perpetuating autoreactive B cells.[13] Autoreactive B cells in spontaneous autoimmunity are seen as surviving because of subversion both of the T cell help pathway and of the feedback signal through B cell receptor, thereby overcoming the negative signals responsible for B cell self-tolerance without necessarily requiring loss of T cell self-tolerance.
  • Molecular mimicry – An exogenous antigen may share structural similarities with certain host antigens; thus, any antibody produced against this antigen (which mimics the self-antigens) can also, in theory, bind to the host antigens, and amplify the immune response. The idea of molecular mimicry arose in the context of rheumatic fever, which follows infection with Group A beta-haemolytic streptococci. Although rheumatic fever has been attributed to molecular mimicry for half a century no antigen has been formally identified (if anything too many have been proposed). Moreover, the complex tissue distribution of the disease (heart, joint, skin, basal ganglia) argues against a cardiac specific antigen. It remains entirely possible that the disease is due to e.g. an unusual interaction between immune complexes, complement components and endothelium.
  • Idiotype cross-reactionIdiotypes英语Idiotypes are antigenic epitopes found in the antigen-binding portion (Fab) of the immunoglobulin molecule. Plotz and Oldstone presented evidence that autoimmunity can arise as a result of a cross-reaction between the idiotype on an antiviral antibody and a host cell receptor for the virus in question. In this case, the host-cell receptor is envisioned as an internal image of the virus, and the anti-idiotype antibodies can react with the host cells.
  • Cytokine dysregulationCytokines have been recently divided into two groups according to the population of cells whose functions they promote: Helper T-cells type 1 or type 2. The second category of cytokines, which include IL-4, IL-10 and TGF-β (to name a few), seem to have a role in prevention of exaggeration of pro-inflammatory immune responses.
  • Dendritic cell apoptosis – immune system cells called dendritic cells present antigens to active lymphocytes. Dendritic cells that are defective in apoptosis can lead to inappropriate systemic lymphocyte activation and consequent decline in self-tolerance.[14]
  • Epitope spreading or epitope drift – when the immune reaction changes from targeting the primary epitope to also targeting other epitopes.[15] In contrast to molecular mimicry, the other epitopes need not be structurally similar to the primary one.
  • Epitope modification or Cryptic epitope exposure – this mechanism of autoimmune disease is unique in that it does not result from a defect in the hematopoietic system. Instead, disease results from the exposure of cryptic N-glycan (polysaccharide) linkages common to lower eukaryotes and prokaryotes on the glycoproteins of mammalian non-hematopoietic cells and organs[16] This exposure of phylogenically primitive glycans activates one or more mammalian innate immune cell receptors to induce a chronic sterile inflammatory state. In the presence of chronic and inflammatory cell damage, the adaptive immune system is recruited and self–tolerance is lost with increased autoantibody production. In this form of the disease, the absence of lymphocytes can accelerate organ damage, and intravenous IgG administration can be therapeutic. Although this route to autoimmune disease may underlie various degenerative disease states, no diagnostics for this disease mechanism exist at present, and thus its role in human autoimmunity is currently unknown.

The roles of specialized immunoregulatory cell types, such as regulatory T cells, NKT cells, γδ T-cells英语γδ T-cells in the pathogenesis of autoimmune disease are under investigation.

Classification

Autoimmune diseases can be broadly divided into systemic and organ-specific or localised autoimmune disorders, depending on the principal clinico-pathologic features of each disease.

Using the traditional “organ specific” and “non-organ specific” classification scheme, many diseases have been lumped together under the autoimmune disease umbrella. However, many chronic inflammatory human disorders lack the telltale associations of B and T cell driven immunopathology. In the last decade[需要解释] it has been firmly established that tissue "inflammation against self" does not necessarily rely on abnormal T and B cell responses.[17]

This has led to the recent proposal that the spectrum of autoimmunity should be viewed along an “immunological disease continuum,” with classical autoimmune diseases at one extreme and diseases driven by the innate immune system at the other extreme. Within this scheme, the full spectrum of autoimmunity can be included. Many common human autoimmune diseases can be seen to have a substantial innate immune mediated immunopathology using this new scheme. This new classification scheme has implications[需要解释] for understanding disease mechanisms and for therapy development.[17]

Diagnosis

Diagnosis of autoimmune disorders largely rests on accurate history and physical examination of the patient, and high index of suspicion[需要解释] against a backdrop of certain abnormalities in routine laboratory tests (example, elevated C-reactive protein).[来源请求]

In several systemic disorders,[需要解释] serological assays which can detect specific autoantibodies can be employed.[来源请求] Localised disorders are best diagnosed by immunofluorescence英语immunofluorescence of biopsy specimens.[来源请求]

Autoantibodies are used to diagnose many autoimmune diseases.[需要解释] The levels of autoantibodies are measured to determine the progress of the disease.[来源请求]

Treatments

Treatments for autoimmune disease have traditionally been immunosuppressive, anti-inflammatory, or palliative.[1] Managing inflammation is critical in autoimmune diseases.[18] Non-immunological therapies, such as hormone replacement in Hashimoto's thyroiditis or Type 1 diabetes mellitus treat outcomes of the autoaggressive response, thus these are palliative treatments. Dietary manipulation limits the severity of celiac disease. Steroidal or NSAID treatment limits inflammatory symptoms of many diseases. IVIG is used for CIDP英语Chronic inflammatory demyelinating polyneuropathy and GBS. Specific immunomodulatory therapies, such as the TNFα antagonists (e.g. etanercept), the B cell depleting agent rituximab, the anti-IL-6 receptor tocilizumab英语tocilizumab and the costimulation blocker abatacept have been shown to be useful in treating RA. Some of these immunotherapies may be associated with increased risk of adverse effects, such as susceptibility to infection.

Helminthic therapy英语Helminthic therapy is an experimental approach that involves inoculation of the patient with specific parasitic intestinal nematodes (helminths). There are currently two closely related treatments available, inoculation with either Necator americanus, commonly known as hookworm英语hookworms, or Trichuris Suis Ova, commonly known as Pig Whipworm Eggs.[19][19][20][21][22][23]

T-cell vaccination英语T-cell vaccination is also being explored as a possible future therapy for autoimmune disorders.[来源请求]

Nutrition and autoimmunity

Vitamin D/Sunlight

Omega-3 Fatty Acids

  • Studies have shown that adequate consumption of omega-3 fatty acids counteracts the effects of arachidonic acids, which contribute to symptoms of autoimmune diseases. Human and animal trials suggest that omega-3 is an effective treatment modality for many cases of Rheumatoid Arthritis, Inflammatory Bowel Disease, Asthma, and Psoriasis.[28]
  • While major depression is not necessarily an autoimmune disease, some of its physiological symptoms are inflammatory and autoimmune in nature. Omega-3 may inhibit production of interferon gamma and other cytokines which cause the physiological symptoms of depression. This may be due to the fact that an imbalance in omega-3 and omega-6 fatty acids, which have opposing effects, is instrumental in the etiology of major depression.[28]

Probiotics/Microflora

  • Various types of bacteria and microflora present in fermented dairy products, especially Lactobacillus casei, have been shown to both stimulate immune response to tumors in mice and to regulate immune function, delaying or preventing the onset of nonobese diabetes. This is particularly true of the Shirota strain of L. casei (LcS). The LcS strain is mainly found in yogurt and similar products in Europe and Japan, and rarely elsewhere.[29]

Antioxidants

  • It has been theorized that free radicals contribute to the onset of type-1 diabetes in infants and young children, and therefore that the risk could be reduced by high intake of antioxidant substances during pregnancy. However, a study conducted in a hospital in Finland from 1997-2002 concluded that there was no statistically significant correlation between antioxidant intake and diabetes risk.[30] This study involved monitoring of food intake through questionnaires, and estimated antioxidant intake on this basis, rather than by exact measurements or use of supplements.

自体免疫性疾病

自体免疫性疾病

自体免疫性疾病
Autoimmune diseases
Young woman with the typical "butterfly rash英语malar rash" found in systemic lupus erythematosus
症状Depends on the condition. Commonly low grade fever, feeling tired[31]
起病年龄Adulthood[31]
类型List of autoimmune diseases英语List of autoimmune diseases (alopecia areata, celiac disease, diabetes mellitus type 1, Graves' disease, inflammatory bowel disease, multiple sclerosis, psoriasis, rheumatoid arthritis, systemic lupus erythematosus, others)[31]
药物Nonsteroidal anti-inflammatory drugs, immunosuppressants, intravenous immunoglobulin[31][32]
患病率24 million / 7% (USA)[31][33]
分类和外部资源
医学专科Rheumatology, immunology, gastroenterology, neurology, dermatology
[编辑此条目的维基数据]

An autoimmune disease is a condition arising from an abnormal immune response英语immune response to a normal body part.[31] There are at least 80 types of autoimmune diseases.[31] Nearly any body part can be involved.[33] Common symptoms include low grade fever and feeling tired.[31] Often symptoms come and go.[31]

The cause is generally unknown.[33] Some autoimmune diseases such as lupus run in families, and certain cases may be triggered by infections or other environmental factors.[31] Some common diseases that are generally considered autoimmune include celiac disease, diabetes mellitus type 1, Graves' disease, inflammatory bowel disease, multiple sclerosis, psoriasis, rheumatoid arthritis, and systemic lupus erythematosus.[31][34] The diagnosis can be difficult to determine.[31]

Treatment depends on the type and severity of the condition.[31] Nonsteroidal anti-inflammatory drugs (NSAIDs) and immunosuppressants are often used.[31] Intravenous immunoglobulin may also occasionally be used.[32] While treatment usually improves symptoms, they do not typically cure the disease.[31]

About 24 million (7%) people in the United States are affected by an autoimmune disease.[31][33] Women are more commonly affected than men.[31] Often they start during adulthood.[31] The first autoimmune diseases were described in the early 1900s.[35]

Signs and symptoms

Rheumatoid arthritis

Autoimmune diseases have a wide variety of different effects. They do tend to have one of three characteristic pathological effects which characterize them as autoimmune diseases:[36]

  1. Damage to or destruction of tissues
  2. Altered organ growth
  3. Altered organ function

It has been estimated that autoimmune diseases are among the leading causes of death among women in the United States in all age groups up to 65 years.[37]

A substantial minority of the population suffers from these diseases, which are often chronic, debilitating, and life-threatening.[来源请求]

There are more than 80 illnesses caused by autoimmunity.[38]

Causes

The cause is generally unknown.[33] Some autoimmune diseases such as lupus run in families, and certain cases may be triggered by infections or other environmental factors.[31] There are more than 100 autoimmune diseases.[39] Some common diseases that are generally considered autoimmune include celiac disease, diabetes mellitus type 1, Graves' disease, inflammatory bowel disease, multiple sclerosis, psoriasis, rheumatoid arthritis, and systemic lupus erythematosus.[31][34]

Pathophysiology

The human immune system typically produces both T cells and B cells that are capable of being reactive with self-antigens, but these self-reactive cells are usually either killed prior to becoming active within the immune system, placed into a state of anergy (silently removed from their role within the immune system due to over-activation), or removed from their role within the immune system by regulatory cells. When any one of these mechanisms fail, it is possible to have a reservoir of self-reactive cells that become functional within the immune system. The mechanisms of preventing self-reactive T cells from being created takes place through negative selection process within the thymus as the T cell is developing into a mature immune cell.

Some infections, such as Campylobacter jejuni, have antigens that are similar (but not identical) to our own self-molecules. In this case, a normal immune response to C. jejuni can result in the production of antibodies that also react to a lesser degree with gangliosides of myelin sheath surrounding peripheral nerves' axons (i.e., Guillain–Barré). A major understanding of the underlying pathophysiology of autoimmune diseases has been the application of genome wide association scans that have identified a degree of genetic sharing among the autoimmune diseases.[40]

Autoimmunity, on the other hand, is the presence of self-reactive immune response (e.g., auto-antibodies, self-reactive T cells), with or without damage or pathology resulting from it.[41] This may be restricted to certain organs (e.g. in autoimmune thyroiditis英语autoimmune thyroiditis) or involve a particular tissue in different places (e.g. Goodpasture's disease which may affect the basement membrane in both the lung and the kidney).

There are many theories as to how an autoimmune disease state arises. Some common ones are listed below.

Cryptic determinants/molecular sequestration

Although it is possible for a potential autoantigen to be spatially sequestered in an immune privileged site within the body (e.g. the eye), mechanisms exist to express even these antigens in a tolerogenic fashion to the immune system. However, it is impossible to induce tolerance (immune unresponsiveness) to all aspects of an autoantigen. This is because under normal physiologic conditions some regions of a self-antigen are not expressed at a sufficient level to induce tolerance. These poorly displayed areas of an antigen are called "cryptic determinants." The immune system maintains a high-affinity repertoire to the cryptic self because the presentation of these determinants was insufficient to induce strong tolerance.[42]

Molecular mimicry

The concept of molecular mimicry describes a situation in which a foreign antigen can initiate an immune response in which a T or B cell component cross-recognizes self. The cross reactive immune response is responsible for the autoimmune disease state.[43] Cross-reactive immune responses to self were first described for antibodies.

Altered glycan theory

According to this theory the effector function of the immune response is mediated by the glycans英语glycans (polysaccharides) displayed by the cells and humoral components of the immune system. Individuals with autoimmunity have alterations in their glycosylation profile such that a proinflammatory immune response is favored. It is further hypothesized that individual autoimmune diseases will have unique glycan signatures.[44]

Hygiene hypothesis

According to the hygiene hypothesis, high levels of cleanliness expose children to fewer antigens than in the past, causing their immune systems to become overactive and more likely to misidentify own tissues as foreign, resulting in autoimmune or allergic conditions such as asthma.[45]

Diagnosis

For a disease to be regarded as an autoimmune disease it needs to answer to Witebsky's postulates (first formulated by Ernest Witebsky英语Ernest Witebsky and colleagues in 1957 and modified in 1994):[46][47]

  • Direct evidence from transfer of disease-causing antibody or disease-causing T lymphocyte white blood cells
  • Indirect evidence based on reproduction of the autoimmune disease in experimental animals
  • Circumstantial evidence from clinical clues

Epidemiology

The first estimate of US prevalence for autoimmune diseases as a group was published in 1997 by Jacobson, et al. They reported US prevalence to be around 9 million, applying prevalence estimates for 24 diseases to a US population of 279 million.[48] Jacobson's work was updated by Hayter & Cook in 2012.[49] This study used Witebsky's postulates, as revised by Rose & Bona,[50] to extend the list to 81 diseases and estimated overall cumulative US prevalence for the 81 autoimmune diseases at 5.0%, with 3.0% for males and 7.1% for females. The estimated community prevalence, which takes into account the observation that many people have more than one autoimmune disease, was 4.5% overall, with 2.7% for males and 6.4% for females.[49]

Research

In both autoimmune and inflammatory diseases, the condition arises through aberrant reactions of the human adaptive or innate immune systems. In autoimmunity, the patient's immune system is activated against the body's own proteins. In chronic inflammatory diseases, neutrophils and other leukocytes are constitutively recruited by cytokines and chemokines, leading to tissue damage.

Mitigation of inflammation by activation of anti-inflammatory genes and the suppression of inflammatory genes in immune cells is a promising therapeutic approach.[51][52][53] There is a body of evidence that once the production of autoantibodies has been initialized, autoantibodies have the capacity to maintain their own production.[54]

Stem cell transplantation is being studied and has shown promising results in certain cases.[55]

History

Traditionally it was believed that the immune system was unable to react against the body's own tissues, a concept described by the German immunologist Paul Ehrlich as "horror autotoxicus". In 1904 this theory was challenged by the discovery of a substance in the serum of patients with paroxysmal cold hemoglobinuria英语paroxysmal cold hemoglobinuria that reacted with red blood cells.[56]

单克隆抗体治疗

单克隆抗体治疗 单克隆抗体治疗 Template:细胞外化疗药物 en:Biologics for immunosuppression

单克隆抗体治疗

Antibody structure and function

Immunoglobulin G (IgG) antibodies are large heterodimeric molecules, approximately 150 kDa and are composed of two kinds of polypeptide chain, called the heavy (~50kDa) and the light chain (~25kDa). The two types of light chains are kappa (κ) and lambda (λ). By cleavage with enzyme papain, the Fab (fragment-antigen binding) part can be separated from the Fc英语Fc region (fragment constant) part of the molecule. The Fab fragments contain the variable domains, which consist of three antibody hypervariable amino acid英语Hypervariable region domains responsible for the antibody specificity embedded into constant regions. The four known IgG subclasses are involved in antibody-dependent cellular cytotoxicity.[57] Antibodies are a key component of the adaptive immune response, playing a central role in both in the recognition of foreign antigens and the stimulation of an immune response to them. The advent of monoclonal antibody technology has made it possible to raise antibodies against specific antigens presented on the surfaces of tumors.[58] Monoclonal antibodies can be acquired in the immune system via passive immunity英语passive immunity or active immunity.The advantage of active monoclonal antibody therapy is the fact that the immune system will produce antibodies long-term, with only a short-term drug administration to induce this response. However, the immune response to certain antigens may be inadequate, especially in the elderly. Additionally, adverse reactions from these antibodies may occur because of long-lasting response to antigens.[59] Passive monoclonal antibody therapy can ensure consistent antibody concentration, and can control for adverse reactions by stopping administration. However, the repeated administration and consequent higher cost for this therapy are major disadvantages.[59]

Monoclonal antibody therapy may prove to be beneficial for cancer, autoimmune diseases, and neurological disorders that result in the degeneration of body cells, such as Alzheimer's disease. Monoclonal antibody therapy can aid the immune system because the innate immune system responds to the environmental factors it encounters by discriminating against foreign cells from cells of the body. Therefore, tumor cells that are proliferating at high rates, or body cells that are dying which subsequently cause physiological problems are generally not specifically targeted by the immune system, since tumor cells are the patient's own cells. Tumor cells, however are highly abnormal, and many display unusual antigens. Some such tumor antigen英语tumor antigens are inappropriate for the cell type or its environment. Monoclonal antibodies can target tumor cells or abnormal cells in the body that are recognized as body cells, but are debilitating to one's health.

History

Monoclonal antibodies for cancer. ADEPT: antibody directed enzyme prodrug therapy英语ADEPT (medicine); ADCC: antibody-dependent cell-mediated cytotoxicity; CDC: complement-dependent cytotoxicity英语complement-dependent cytotoxicity; MAb, monoclonal antibody; scFv英语scFv, single-chain Fv fragment.[60]

Immunotherapy developed in the 1970s following the discovery of the structure of antibodies and the development of hybridoma英语hybridoma technology, which provided the first reliable source of monoclonal antibodies.[61][62] These advances allowed for the specific targeting of tumors both in vitro and in vivo. Initial research on malignant英语malignant neoplasms found mAb therapy of limited and generally short-lived success with blood malignancies.[63][64] Treatment also had to be tailored to each individual patient, which was impracticable in routine clinical settings.

Four major antibody types that have been developed are murine, chimeric英语Fusion protein, humanised英语Humanized antibody and human. Antibodies of each type are distinguished by suffixes on their name.

Murine

Initial therapeutic antibodies were murine analogues英语analog (chemistry) (suffix -omab). These antibodies have: a short half-life in vivo (due to immune complex英语immune complex formation), limited penetration into tumour sites and inadequately recruit host effector functions.[65] Chimeric and humanized antibodies have generally replaced them in therapeutic antibody applications.[66] Understanding of proteomics has proven essential in identifying novel tumour targets.

Initially, murine antibodies were obtained by hybridoma technology, for which Jerne, Köhler and Milstein received a Nobel prize. However the dissimilarity between murine and human immune systems led to the clinical failure of these antibodies, except in some specific circumstances. Major problems associated with murine antibodies included reduced stimulation of cytotoxicity and the formation complexes after repeated administration, which resulted in mild allergic reactions and sometimes anaphylactic shock.[65] Hybridoma英语Hybridoma technology has been replaced by recombinant DNA technology, transgenic mice and phage display.[66]

Chimeric and humanized

To reduce murine antibody immunogenicity (attacks by the immune system against the antibody), murine molecules were engineered to remove immunogenic content and to increase immunologic efficiency.[65] This was initially achieved by the production of chimeric (suffix -ximab) and humanized antibodies (suffix -zumab). Chimeric antibodies are composed of murine variable regions fused onto human constant regions. Taking human gene sequences from the kappa light chain and the IgG1 heavy chain results in antibodies that are approximately 65% human. This reduces immunogenicity, and thus increases serum half-life.

Humanised antibodies are produced by grafting murine hypervariable regions on amino acid domains into human antibodies. This results in a molecule of approximately 95% human origin. Humanised antibodies bind antigen much more weakly than the parent murine monoclonal antibody, with reported decreases in affinity of up to several hundredfold.[67][68] Increases in antibody-antigen binding strength have been achieved by introducing mutations into the complementarity determining regions (CDR),[69] using techniques such as chain-shuffling, randomization of complementarity-determining regions and antibodies with mutations within the variable regions induced by error-prone PCR, E. coli mutator strains and site-specific mutagenesis.[70]

Human monoclonal antibodies

Human monoclonal antibodies (suffix -umab) are produced using transgenic mice or phage display libraries by transferring human immunoglobulin genes into the murine genome and vaccinating the transgenic mouse against the desired antigen, leading to the production of appropriate monoclonal antibodies.[66] Murine antibodies in vitro are thereby transformed into fully human antibodies.[58]

The heavy and light chains of human IgG proteins are expressed in structural polymorphic (allotypic) forms. Human IgG allotype英语allotype (immunology) is one of the many factors that can contribute to immunogenicity.[71][72]

Targeted conditions

Cancer

Anti-cancer monoclonal antibodies can be targeted against malignant cells by several mechanisms. Ramucirumab is a recombinant human monoclonal antibody and is used in the treatment of advanced malignancies.[73] In childhood lymphoma, phase I and II studies have found a positive effect of using antibody therapy.[74]

Autoimmune diseases

Monoclonal antibodies used for autoimmune diseases include infliximab英语infliximab and adalimumab英语adalimumab, which are effective in rheumatoid arthritis, Crohn's disease and ulcerative colitis by their ability to bind to and inhibit TNF-α.[75] Basiliximab英语Basiliximab and daclizumab英语daclizumab inhibit IL-2 on activated T cells and thereby help preventing acute rejection of kidney transplants.[75] Omalizumab英语Omalizumab inhibits human immunoglobulin E (IgE) and is useful in moderate-to-severe allergic asthma.

Alzheimer's disease

Alzheimer’s disease (AD) is a multi-faceted, age-dependent, progressive neurodegenerative disorder, and is a major cause of dementia.[76] According to the Amyloid hypothesis英语Amyloid hypothesis, the accumulation of extracellular amyloid beta英语amyloid betapeptides (Aβ) into plaques via oligomerization leads to hallmark symptomatic conditions of AD through synaptic dysfunction and neurodegeneration.[77] Immunotherapy via exogenous monoclonal antibody (MAB) administration has been known to treat various central nervous disorders, such as AD, by inhibiting Aβ-oligomerization thereby preventing neurotoxicity. However, MABs are large for passive protein channels and are therefore inefficient due to the blood-brain barrier preventing MAB passage into the brain. However, the Peripheral Sink hypothesis proposes a mechanism where MABs may not need to cross the blood-brain barrier.[78] Therefore, many research studies are being conducted from failed attempts to treat AD in the past.[77]

However, anti-Aβ vaccines can promote antibody-mediated clearance of Aβ plaques in transgenic mice models with amyloid precursor proteins (APP), and can reduce cognitive impairments.[76] Vaccines can stimulate the immune system to produce its own antibodies,[79] in this case by introducing Aβ into transgenic animal models, known as active immunization英语active immunization. They can also introduce antibodies into animal models, known as passive immunization英语passive immunization. In mice expressing APP, both active and passive immunization of anti-Aβ antibodies has been shown to be effective in clearing plaques, and can improve cognitive function.[77]. Therefore, several clinical trials using passive and active immunization approaches by development of certain drugs approved by the FDA are currently underway, and are expected to yield results in a couple of years.[77] The implementation of these drugs is during the onset of AD. Other research and drug development for early intervention and AD prevention is ongoing. Various drugs that are under research to treat AD include Bapineuzumab, Solanezumab, and Gautenerumab.

Bapineuzumab

Bapineuzumab, a humanized anti-aβ MAB, is directed against the N-terminus of Aβ. Phase II clinical trials of Bapineuzumab in mild to moderate AD patients resulted in reduced Aβ concentration in the brain. However, in patients with increased apolipoprotein (APOE) e4 carriers, Bapineuzumab treatment is also accompanied by vasogenic edema英语vasogenic edema,[80] a cytotoxic condition where the blood brain barrier has been disrupted thereby affecting white matter from excess accumulation of fluid from capillaries in intracellular and extracellular spaces of the brain.[81] In Phase III clinical trials, Bapineuzumab treatment is associated with reduced rate of accumulation of Aβ in the brain in APOE e4 patients, and no significant reduction of Aβ concentration in APOE e4 patients and non-APOE e4 patients. Therefore, Aβ plaque concentration was not reduced, and there is no significant clinical benefits in cognitive functioning. Bapineuzumab was discontinued after failing in Phase III clinical trial[81]

Solanezumab

Solanezumab, an anti-aβ MAB, targets the N-terminus of Aβ. In Phase I and Phase II of clinical trials, Solanezumab treatment resulted in cerebrospinal fluid elevation of Aβ, thereby showing a reduced concentration of Aβ plaques. Additionally, there are no associated adverse side effects. Phase III clinical trials of Solanezumab brought about significant reduction in cognitive impairment in patients with mild AD, but not in patients with severe AD. However, Aβ concentration did not significantly change, along with other AD biomarkers, including phospho-tau expression, and hippocampal volume. Phase III clinical trials are currently ongoing.[78]

Preventive trials

Failure of several drugs in Phase III clinical trials has led to AD prevention and early intervention for onset AD treatment endeavours. Passive anti-Aβ MAB treatment can be used for preventive attempts to modify AD progression before it causes extensive brain damage and symptoms. Trials using MAB treatment for patients positive for genetic risk factors, and elderly patients positive for indicators of AD are underway. This includes anti-AB treatment in Asymptomatic Alzheimer's Disease (A4), the Alzheimer’s Prevention Initiative (API), and DIAN-TU.[78] The A4 study on older individuals who are positive for indicators of AD but are negative for genetic risk factors will test Solanezumab in Phase III Clinical Trials, as a follow up of previous Solanezumab studies.[78] DIAN-TU, launched in December 2012, focuses on young patients positive for genetic mutations that are risks for AD. This study uses Solanezumab and Gautenerumab. Gautenerumab, the first fully human MAB that preferentially interacts with oligomerized Aβ plaques in the brain, caused significant reduction in Aβ concentration in Phase I clinical trials, preventing plaque formation and concentration without altering plasma concentration of the brain. Phase II and III clinical trials are currently being conducted.[78]

Therapy types

Radioimmunotherapy

Radioimmunotherapy英语Radioimmunotherapy (RIT) involves the use of radioactively-conjugated murine antibodies against cellular antigens. Most research involves their application to lymphomas, as these are highly radio-sensitive malignancies. To limit radiation exposure, murine antibodies were chosen, as their high immunogenicity promotes rapid tumor clearance. Tositumomab英语Tositumomab is an example used for non-Hodgkin's lymphoma.

Antibody-directed enzyme prodrug therapy

Antibody-directed enzyme prodrug therapy英语ADEPT (medicine) (ADEPT) involves the application of cancer-associated monoclonal antibodies that are linked to a drug-activating enzyme. Systemic administration of a non-toxic agent results in the antibody's conversion to a toxic drug, resulting in a cytotoxic effect that can be targeted at malignant cells. The clinical success of ADEPT treatments is limited.[82]

Antibody-drug conjugates

Antibody-drug conjugate英语Antibody-drug conjugates (ADCs) are antibodies linked to one or more drug molecules. Typically when the ADC meets the target cell (e.g. a cancerous cell) the drug is released to kill it. Many ADCs are in clinical development. 截至2016年 (2016-Missing required parameter 1=month!) a few have been approved.

Immunoliposome therapy

Immunoliposomes are antibody-conjugated liposomes. Liposomes can carry drugs or therapeutic nucleotides and when conjugated with monoclonal antibodies, may be directed against malignant cells. Immunoliposomes have been successfully used in vivo to convey tumour-suppressing genes into tumours, using an antibody fragment against the human transferrin receptor. Tissue-specific gene delivery using immunoliposomes has been achieved in brain and breast cancer tissue.[83]

Checkpoint therapy

Checkpoint therapy uses antibodies and other techniques to circumvent the defenses that tumors use to suppress the immune system. Each defense is known as a checkpoint. Compound therapies combine antibodies to suppress multiple defensive layers. Known checkpoints include CTLA-4 targeted by ipilimumab, PD-1英语PD-1 targeted by nivolumab and pembrolizumab and the tumor microenvironment.[84]

The tumor microenvironment (TME) features prevents the recruitment of T cells to the tumor. Ways include chemokine CCL2 nitration, which traps T cells in the stroma. Tumor vasculature helps tumors preferentially recruit other immune cells over T cells, in part through endothelial cell (EC)–specific expression of FasL英语FasL, ETBR英语Endothelin_B_receptor, and B7H3. Myelomonocytic英语Myelomonocytic and tumor cells can up-regulate expression of PD-L1, partly driven by hypoxic conditions and cytokine production, such as IFNβ. Aberrant metabolite production in the TME, such as the pathway regulation by IDO英语Indoleamine 2,3-dioxygenase, can affect T cell functions directly and indirectly via cells such as Treg cells. CD8 cells can be suppressed by B cells regulation of TAM phenotypes. Cancer-associated fibroblasts (CAFs) have multiple TME functions, in part through extracellular matrix (ECM)–mediated T cell trapping and CXCL12-regulated T cell exclusion.[85]

FDA-approved therapeutic antibodies

The first FDA-approved therapeutic monoclonal antibody was a murine IgG2a CD3 specific transplant rejection drug, OKT3英语OKT3 (also called muromonab), in 1986. This drug found use in solid organ transplant recipients who became steroid resistant.[86] Hundreds of therapies are undergoing clinical trials. Most are concerned with immunological and oncological targets.

FDA approved therapeutic monoclonal antibodies
Antibody Brand name Company Approval date Route Type Target Indication
(Targeted disease)
BLA STN Drug Label
abciximab英语abciximab ReoPro Centocor英语Centocor 12/22/1994 intravenous chimeric Fab GPIIb/IIIa英语GPIIb/IIIa Percutaneous coronary intervention 103575 Link
adalimumab英语adalimumab Humira Abbvie 12/31/2002 subcutaneous fully human TNF英语TNF Rheumatoid arthritis 125057 Link
adalimumab-atto英语adalimumab-atto Amjevita Amgen 9/23/2016 subcutaneous fully human, biosimilar TNF英语TNF Rheumatoid arthritis
Juvenile idiopathic arthritis
Psoriatic arthritis
Ankylosing spondylitis
Crohn's disease
Ulcerative colitis
Plaque psoriasis
761024 Link
ado-trastuzumab emtansine英语ado-trastuzumab emtansine Kadcyla Genentech 2/22/2013 intravenous humanized, antibody-drug conjugate英语antibody-drug conjugate HER2 Metastatic breast cancer 125427 Link
alemtuzumab英语alemtuzumab Campath, Lemtrada Genzyme 5/7/2001 intravenous humanized CD52英语CD52 B-cell chronic lymphocytic leukemia 103948 Link
alirocumab英语alirocumab Praluent Sanofi Aventis 7/24/2015 subcutaneous fully human PCSK9英语PCSK9 Heterozygous familial hypercholesterolemia
Refractory hypercholesterolemia
125559 Link
atezolizumab Tecentriq Genentech 5/18/2016 intravenous humanized PD-L1 Urothelial carcinoma英语Urothelial carcinoma 761034 Link
atezolizumab Tecentriq Genentech 10/18/2016 intravenous humanized PD-L1 Urothelial carcinoma英语Urothelial carcinoma
Metastatic non-small cell lung cancer英语non-small cell lung cancer
761041 Link
avelumab英语avelumab Bavencio EMD Serono英语EMD Serono 3/23/2017 intravenous fully human PD-L1 Metastatic Merkel cell carcinoma英语Merkel cell carcinoma 761049 Link
basiliximab英语basiliximab Simulect Novartis 5/12/1998 intravenous chimeric IL2RA英语IL2RA Prophylaxis of acute organ rejection in renal transplant英语renal transplant 103764 Link
belimumab英语belimumab Benlysta Human Genome Sciences英语Human Genome Sciences 3/9/2011 intravenous fully human BLyS英语BLyS Systemic lupus erythematosus 125370 Link
bevacizumab Avastin Genentech 2/26/2004 intravenous humanized VEGF Metastatic colorectal cancer 125085 Link
bezlotoxumab英语bezlotoxumab Zinplava Merck 10/21/2016 intravenous fully human Clostridium difficile toxin B英语Clostridium difficile toxin B Prevent recurrence of Clostridium difficile infection 761046 Link
blinatumomab英语blinatumomab Blincyto Amgen 12/3/2014 intravenous mouse, bispecific CD19 Precursor B-cell acute lymphoblastic leukemia 125557 Link
brentuximab vedotin英语brentuximab vedotin Adcetris Seattle Genetics英语Seattle Genetics 9/19/2011 intravenous chimeric, antibody-drug conjugate英语antibody-drug conjugate CD30英语CD30 Hodgkin lymphoma
Anaplastic large-cell lymphoma英语Anaplastic large-cell lymphoma
125388 Link
brodalumab英语brodalumab Siliq Valeant英语Valeant 2/15/2017 subcutaneous chimeric IL17RA英语IL17RA Plaque psoriasis 761032 Link
canakinumab英语canakinumab Ilaris Novartis 6/17/2009 subcutaneous fully human IL1B英语IL1B Cryopyrin-associated periodic syndrome英语Cryopyrin-associated periodic syndrome 125319 Link
capromab pendetide英语capromab pendetide ProstaScint Cytogen 10/28/1996 intravenous murine, radiolabeled PSMA英语PSMA Diagnostic imaging agent in newly diagnosed prostate cancer or post-prostatectomy英语prostatectomy 103608 Link
certolizumab pegol英语certolizumab pegol Cimzia UCB (company)英语UCB (company) 4/22/2008 subcutaneous humanized TNF英语TNF Crohn's disease 125160 Link
cetuximab Erbitux ImClone Systems英语ImClone Systems 2/12/2004 intravenous chimeric EGFR Metastatic colorectal carcinoma 125084 Link
daclizumab英语daclizumab Zenapax Roche 12/10/1997 intravenous humanized IL2RA英语IL2RA Prophylaxis of acute organ rejection in renal transplant英语renal transplant 103749 Link
daclizumab英语daclizumab Zinbryta Biogen 5/27/2016 subcutaneous humanized IL2R英语IL2R Multiple sclerosis 761029 Link
daratumumab英语daratumumab Darzalex Janssen Biotech英语Janssen Biotech 11/16/2015 intravenous fully human CD38英语CD38 Multiple myeloma 761036 Link
denosumab英语denosumab Prolia, Xgeva Amgen 6/1/2010 subcutaneous fully human RANKL Postmenopausal women with osteoporosis 125320 Link
dinutuximab英语dinutuximab Unituxin United Therapeutics英语United Therapeutics 3/10/2015 intravenous chimeric GD2英语GD2 Pediatric high-risk neuroblastoma 125516 Link
dupilumab英语dupilumab Dupixent Regeneron Pharmaceuticals 3/28/2017 subcutaneous fully human IL4RA英语IL4RA Atopic dermatitis, asthma 761055 Link
durvalumab英语durvalumab Imfinzi AstraZeneca 5/1/2017 intravenous fully human PD-L1 Urothelial carcinoma英语Urothelial carcinoma 761069 Link
eculizumab英语eculizumab Soliris Alexion英语Alexion 3/16/2007 intravenous humanized Complement component 5英语Complement component 5 Paroxysmal nocturnal hemoglobinuria 125166 Link
elotuzumab英语elotuzumab Empliciti Bristol-Myers Squibb 11/30/2015 intravenous humanized SLAMF7英语SLAMF7 Multiple myeloma 761035 Link
evolocumab英语evolocumab Repatha Amgen 8/27/2015 subcutaneous fully human PCSK9英语PCSK9 Heterozygous familial hypercholesterolemia
Refractory hypercholesterolemia
125522 Link
golimumab英语golimumab Simponi Centocor英语Centocor 4/24/2009 subcutaneous fully human TNF英语TNF Rheumatoid arthritis
Psoriatic arthritis
Ankylosing spondylitis
125289 Link
golimumab英语golimumab Simponi Aria Janssen Biotech英语Janssen Biotech 7/18/2013 intravenous fully human TNF英语TNF Rheumatoid arthritis 125433 Link
ibritumomab tiuxetan英语ibritumomab tiuxetan Zevalin Spectrum Pharmaceuticals英语Spectrum Pharmaceuticals 2/19/2002 intravenous murine, radioimmunotherapy CD20英语CD20 Relapsed or refractory low-grade, follicular, or transformed B-cell non-Hodgkin's lymphoma 125019 Link
idarucizumab Praxbind Boehringer Ingelheim 10/16/2015 intravenous humanized Fab dabigatran Emergency reversal of anticoagulant dabigatran 761025 Link
infliximab英语infliximab Remicade Centocor英语Centocor 8/24/1998 intravenous chimeric TNF alpha Crohn's disease 103772 Link
infliximab-abda Renflexis Samsung Bioepis 4/21/2017 intravenous chimeric, biosimilar TNF英语TNF Crohn's disease
Ulcerative colitis
Rheumatoid arthritis
Ankylosing spondylitis
Psoriatic arthritis
Plaque psoriasis
761054 Link
infliximab-dyyb Inflectra Celltrion Healthcare英语Celltrion Healthcare 4/5/2016 intravenous chimeric, biosimilar TNF英语TNF Crohn's disease
Ulcerative colitis
Rheumatoid arthritis
Ankylosing spondylitis
Psoriatic arthritis
Plaque psoriasis
125544 Link
ipilimumab英语ipilimumab Yervoy Bristol-Myers Squibb 3/25/2011 intravenous fully human CTLA-4 Metastatic melanoma 125377 Link
ixekizumab英语ixekizumab Taltz Eli Lilly英语Eli Lilly 3/22/2016 subcutaneous humanized IL17A英语IL17A Plaque psoriasis 125521 Link
mepolizumab英语mepolizumab Nucala GlaxoSmithKline 11/4/2015 subcutaneous humanized IL5英语Interleukin 5 Severe asthma 125526 Link
natalizumab英语natalizumab Tysabri Biogen Idec 11/23/2004 intravenous humanized alpha-4 integrin Multiple sclerosis 125104 Link
necitumumab英语necitumumab Portrazza Eli Lilly英语Eli Lilly 11/24/2015 intravenous fully human EGFR Metastatic squamous non-small cell lung carcinoma英语non-small cell lung carcinoma 125547 Link
nivolumab Opdivo Bristol-Myers Squibb 12/22/2014 intravenous fully human PD-1英语PD-1 Metastatic melanoma 125554 Link
nivolumab Opdivo Bristol-Myers Squibb 3/4/2015 intravenous fully human PD-1英语PD-1 Metastatic squamous non-small cell lung carcinoma英语non-small cell lung carcinoma 125527 Link
obiltoxaximab英语obiltoxaximab Anthem Elusys Therapeutics英语Elusys Therapeutics 3/18/2016 intravenous chimeric Protective antigen of the Anthrax toxin英语Anthrax toxin Inhalational anthrax 125509 Link
obinutuzumab英语obinutuzumab Gazyva Genentech 11/1/2013 intravenous humanized CD20英语CD20 Chronic lymphocytic leukemia 125486 Link
ocrelizumab英语ocrelizumab Ocrevus Genentech 3/28/2017 intravenous humanized CD20英语CD20 Multiple sclerosis 761053 Link
ofatumumab英语ofatumumab Arzerra Glaxo Grp 10/26/2009 intravenous fully human CD20英语CD20 Chronic lymphocytic leukemia 125326 Link
olaratumab英语olaratumab Lartruvo Eli Lilly英语Eli Lilly 10/19/2016 intravenous fully human PDGFRA英语PDGFRA Soft tissue sarcoma英语Soft tissue sarcoma 761038 Link
omalizumab英语omalizumab Xolair Genentech 6/20/2003 subcutaneous humanized IgE Moderate to severe persistent asthma 103976 Link
palivizumab英语palivizumab Synagis MedImmune英语MedImmune 6/19/1998 intramuscular humanized F protein of RSV Respiratory syncytial virus 103770 Link
panitumumab英语panitumumab Vectibix Amgen 9/27/2006 intravenous fully human EGFR Metastatic colorectal cancer 125147 Link
pembrolizumab Keytruda Merck 9/4/2014 intravenous humanized PD-1英语PD-1 Metastatic melanoma 125514 Link
pertuzumab Perjeta Genentech 6/8/2012 intravenous humanized HER2 Metastatic breast cancer 125409 Link
ramucirumab英语ramucirumab Cyramza Eli Lilly英语Eli Lilly 4/21/2014 intravenous fully human VEGFR2英语VEGFR2 Gastric cancer 125477 Link
ranibizumab Lucentis Genentech 6/30/2006 intravitreal injection humanized VEGFR1英语VEGFR1
VEGFR2英语VEGFR2
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raxibacumab英语raxibacumab Raxibacumab Human Genome Sciences英语Human Genome Sciences 12/24/2012 intravenous fully human Protective antigen of Bacillus anthracis Inhalational anthrax 125349 Link
reslizumab英语reslizumab Cinqair Teva 3/23/2016 intravenous humanized IL5英语Interleukin 5 Severe asthma 761033 Link
rituximab Rituxan Genentech 11/26/1997 intravenous chimeric CD20英语CD20 B-cell non-Hodgkin's lymphoma 103705 Link
secukinumab Cosentyx Novartis 1/21/2015 subcutaneous fully human IL17A英语IL17A Plaque psoriasis 125504 Link
siltuximab英语siltuximab Sylvant Janssen Biotech英语Janssen Biotech 4/23/2014 intravenous chimeric IL6英语Interleukin 6 Multicentric Castleman's disease英语Castleman's disease 125496 Link
tocilizumab英语tocilizumab Actemra Genentech 1/8/2010 intravenous humanized IL6R英语IL6R Rheumatoid arthritis 125276 Link
tocilizumab英语tocilizumab Actemra Genentech 10/21/2013 intravenous
subcutaneous
humanized IL6R英语IL6R Rheumatoid arthritis
Polyarticular juvenile idiopathic arthritis
Systemic juvenile idiopathic arthritis
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trastuzumab Herceptin Genentech 9/25/1998 intravenous humanized HER2 Metastatic breast cancer 103792 Link
ustekinumab英语ustekinumab Stelara Centocor英语Centocor 9/25/2009 subcutaneous fully human IL12英语Interleukin 12
IL23英语Interleukin 23
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ustekinumab英语ustekinumab Stelara Janssen Biotech英语Janssen Biotech 9/23/2016 subcutaneous
intravenous
fully human IL12英语Interleukin 12
IL23英语Interleukin 23
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Psoriatic arthritis
Crohn's disease
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vedolizumab英语vedolizumab Entyvio Takeda英语Takeda 5/20/2014 intravenous humanized integrin receptor Ulcerative colitis
Crohn's disease
125476 Link
sarilumab英语sarilumab Kevzara Sanofi Aventis 5/22/17 subcutaneous fully human IL6R英语IL6R Rheumatoid arthritis 761037 Link
rituximab and hyaluronidase英语hyaluronidase Rituxan Hycela Genentech 6/22/17 subcutaneous chimeric, co-formulated CD20英语CD20 Follicular lymphoma英语Follicular lymphoma
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guselkumab英语guselkumab Tremfya Janssen Biotech英语Janssen Biotech 7/13/17 subcutaneous fully human IL23英语Interleukin 23 Plaque psoriasis 761061 Link
inotuzumab ozogamicin英语inotuzumab ozogamicin Besponsa Wyeth 8/17/17 intravenous humanized, antibody-drug conjugate英语antibody-drug conjugate CD22 Precursor B-cell acute lymphoblastic leukemia 761040 Link
adalimumab-adbm Cyltezo Boehringer Ingelheim 8/25/17 subcutaneous fully human, biosimilar TNF英语TNF Rheumatoid arthritis
Juvenile idiopathic arthritis
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761058 Link
gemtuzumab ozogamicin英语gemtuzumab ozogamicin Mylotarg Wyeth 9/1/17 intravenous humanized, antibody-drug conjugate英语antibody-drug conjugate CD33 Acute myeloid leukemia 761060 Link
bevacizumab-awwb Mvasi Amgen 9/14/17 intravenous humanized, biosimilar VEGF Metastatic colorectal cancer
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Glioblastoma
Metastatic renal cell carcinoma英语renal cell carcinoma
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761028 Link
benralizumab英语benralizumab Fasenra Astrazeneca 11/14/17 subcutaneous humanized interleukin-5 receptor alpha subunit Severe asthma, eosinophilic phenotype 761070 Link
emicizumab-kxwh Hemlibra Genentech 11/16/17 subcutaneous humanized, bispecific Factor IXa, Factor X英语Factor X Hemophilia A英语Hemophilia A (congenital Factor VIII英语Factor VIII deficiency) with Factor VIII inhibitors. 761083 Link
trastuzumab-dkst Ogivri Mylan 12/1/17 intravenous humanized, biosimilar HER2 HER2-overexpressing breast cancer, metaststic gastric or gastroesophageal junction adenocarcinoma 761074 Link
infliximab-qbtx Ixifi Pfizer 12/13/17 intravenous chimeric, biosimilar TNF英语TNF Crohn's disease
Ulcerative colitis
Rheumatoid arthritis
Ankylosing spondylitis
Psoriatic arthritis
Plaque psoriasis
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ibalizumab-uiyk Trogarzo TaiMed Biologics 3/6/18 intravenous humanized CD4 HIV 761065 Link
tildrakizumab-asmn英语tildrakizumab-asmn Ilumya Merck 3/20/18 subcutaneous humanized IL23英语Interleukin 23 Plaque psoriasis 761067 Link
burosumab-twza英语burosumab-twza Crysvita Ultragenyx 4/17/18 subcutaneous fully human FGF23英语FGF23 X-linked hypophosphatemia英语X-linked hypophosphatemia 761068 Link
erenumab-aooe英语erenumab-aooe Aimovig Amgen 5/17/18 subcutaneous fully human CGRP英语CGRP receptor Migraine headache prevention 761077 Link

Tositumomab英语Tositumomab - Bexxar - 2003 - CD20英语CD20

Mogamulizumab英语Mogamulizumab - Poteligeo - August 2018 - CCR4英语CCR4

Moxetumomab pasudotox英语Moxetumomab pasudotox - Lumoxiti - Sept 2018 - CD22

Cemiplimab英语Cemiplimab - Libtayo - Sept 2018 - PD-1英语PD-1

Polatuzumab vedotin英语Polatuzumab vedotin - Polivy - June 2019 - CD79B英语CD79B

Recently, the bispecific antibodies英语bispecific antibodies, a novel class of therapeutic antibodies, have yielded promising results in clinical trials. In April 2009, the bispecific antibody catumaxomab英语catumaxomab was approved in the European Union.[87][88]

Economics

Since 2000, the therapeutic market for monoclonal antibodies has grown exponentially. In 2006, the “big 5” therapeutic antibodies on the market were bevacizumab, trastuzumab (both oncology), adalimumab英语adalimumab, infliximab英语infliximab (both autoimmune and inflammatory disorders, ‘AIID’) and rituximab (oncology and AIID) accounted for 80% of revenues in 2006. In 2007, eight of the 20 best-selling biotechnology drugs in the U.S. are therapeutic monoclonal antibodies.[89] This rapid growth in demand for monoclonal antibody production has been well accommodated by the industrialization of mAb manufacturing.[90]

结核病

结核病

色素沉着绒毛结节性滑膜炎

色素沉着绒毛结节性滑膜炎

色素沉着绒毛结节性滑膜炎

Signs and symptoms

In general, pigmented villonodular synovitis often manifests initially as sudden onset, unexplained joint swelling and pain; the joint swelling is disproportionate to the amount of pain the patient feels at first. Decreased motion and increased pain occur as the disease state progresses as well as locking of the joint. The localized form often manifests initially as a painless, slow-growing mass and progresses to the other common symptoms of PVNS. The swelling often feels warm to the touch.[91] Diffuse PVNS symptoms are often confused with those of rheumatoid arthritis.[92] While pigmented villonodular synovitis can occur in both pediatric and geriatric patients, it is more common with ages 20–50.[91]

Complications

PVNS is locally aggressive and can spread to surrounding tissues, causing bone erosion and tissue damage. If not treated early, it can spread to areas outside the joint, extra-articular, and potentially cause permanent loss of range as well as intense pain.[93][94] The disorder also has, on average, a 45% rate of recurrence.[95]

Causes

The exact cause is unknown. Some doctors believe it is caused by abnormal metabolism of fat. Others think it may be caused by repetitive inflammation. Some feel that blood within the joint may cause the inflammatory change.[96] Risk factors for PVNS developing are not yet understood. However, a common theme is a trauma experienced to the joint prior to the onset of symptoms.[97]

Diagnosis

Micrograph of PVNS showing pigmented hemosiderin英语hemosiderin-laden macrophages (brown/red). H&E stain.

PVNS is radiologically diagnosed by magnetic resonance imaging (MRI). The disorder is difficult to identify and is often not diagnosed for four years or more after presentation due to nonspecific symptoms or a general paucity of symptoms.[95]

Classification

Pigmented villonodular synovitis, described distinctly in 1941 by Charles J. Sutro, L. Lichtenstein, and H.L. Jafe,[95] comes in two forms: localized and diffuse. Diffuse PVNS affects the entire synovium and typically occurs in large joints such as the knee or hip. Localized, or nodular, PVNS is less common than the diffuse form and typically occurs in smaller joints such as the hands and feet. Localized PVNS often arises in the form of a large benign tumour英语giant cell tumor of the tendon sheath on the tendon sheaths of the joint.[91] As the tumor grows in the joint, it damages the surrounding bone and tissues.[92] Localized PVNS is predominantly found in females and is frequently found in the fingers. Although rare, localized PVNS may develop in large joints. In either case, the knee is the most commonly affected joint (80% of cases), followed by the hip, and less commonly the ankles and shoulders.[91] PVNS is generally found more in men than women.[98] 2 cases per million population; incidence of the localized form is 9 cases per million.

Pathology

The synovial fluid of the joint is often grossly hemorrhagic.[99]

PVNS, under the microscope, looks as the name of the condition suggests; it is composed of nodules and/or villi and has an abundant number of (pigmented) hemosiderin英语hemosiderin-laden macrophages.

Treatment

Once PVNS is confirmed by biopsy of the synovium of an affected joint, an arthroscopic or open synovectomy英语synovectomy of the affected area is the most common treatment. Bone lesions英语lesions caused by the disorder are removed and bone grafting英语bone grafting is performed as needed. Because diffuse PVNS has a relatively high rate of recurrence, radiation therapy or chemotherapy may be considered as a treatment option. In some cases, a total joint replacement is needed to relieve symptoms when PVNS causes significant joint destruction.[100]

费尔蒂症候群

费尔蒂症候群

费尔蒂症候群

Signs and symptoms

The symptoms of Felty's syndrome are similar to those of rheumatoid arthritis. Patients suffer from painful, stiff, and swollen joints, most commonly in the joints of the hands, feet, and arms. In some affected individuals, Felty's syndrome may develop during a period when the symptoms and physical findings associated with rheumatoid arthritis have subsided or are not present; in this case, Felty's syndrome may remain undiagnosed. In more rare instances, the development of Felty's syndrome may precede the development of the symptoms and physical findings associated with rheumatoid arthritis.

Felty's syndrome is also characterized by an abnormally enlarged spleen (splenomegaly英语splenomegaly) and abnormally low levels of certain white blood cells (neutropenia). As a result of neutropenia, affected individuals are increasingly susceptible to certain infections. Keratoconjunctivitis sicca may occur due to secondary Sjögren's syndrome. Individuals with Felty's syndrome may also experience fever, weight loss, and/or fatigue. In some cases, affected individuals may have discoloration (abnormal brown pigmentation) of the skin, particularly of the leg, sores (ulcers) on the lower leg, and/or an abnormally large liver (hepatomegaly英语hepatomegaly). In addition, affected individuals may have abnormally low levels of circulating red blood cells (anemia), a decrease in circulating blood platelets that assist in blood clotting functions (thrombocytopenia英语thrombocytopenia), abnormal liver function tests and/or inflammation of the blood vessels (vasculitis).[101]

Complications

Causes

The cause of Felty's syndrome is unknown, but it has been found to be more common in those with chronic rheumatoid arthritis. Some patients share the HLA-DR4英语HLA-DR4 serotype. This syndrome is mostly present in people having extra articular manifestations of rheumatoid arthritis. People with this syndrome are at risk of infection because they have a low white blood cell count.[102]

Mechanism

The underlying pathogenesis of Felty's syndrome is not clear.

Rheumatoid Arthritis

A 65 year old patient with rheumatoid arthritis displaying swan neck deformity.

Rheumatoid arthritis is an autoimmune disease that is characterized by inflammation of the synovial joints due to attack by the body's own immune system. In this condition, the white blood cells travel through the blood stream to the synovial joints and release pro-inflammatory cytokines upon arrival. The result of this chemical release causes the synovial cells to release harmful chemicals in response as well as begin the growth of new blood vessels, forming a pannus英语pannus. The pannus receives blood supply from the newly formed vessels and grows inward, invading the articular cartilage英语articular cartilage and bone within the joint. The damage to the once healthy tissue causes inflammation and ultimately fluid build-up in the joint. An accumulation of fluid results and the joints swell, slowly decreasing the space that keeps the bones from touching. If this condition is not treated, the joint space will completely narrow, causing ankylosis英语ankylosis. At the advanced stage of ankylosis英语ankylosis, joint mobility is completely occluded. Early presentation is commonly seen in the joints of hands and of the feet. As the disease progresses it can be seen in the knees, wrists, hips, and shoulders. This condition can affect and damage several other body systems such as the eyes, heart, lungs, and blood vessels.[103]

Rheumatoid arthritis is a condition that cannot be cured but symptoms can be treated using certain medications alone or in conjunction. Due to the increased inflammatory response of the body's immune system, this condition can cause a reduction in red and white blood cells.[104]

Neutropenia

In Felty's syndrome, chronic activation of neutrophils progresses to neutropenia and unabated infections.[26] Neutropenia is a decreased concentration of neutrophils in the blood. Neutrophils are the most abundant cells among white blood cells and play an important role in the immune system by destroying bacteria via phagocytosis. Inflammatory chemicals draw neutrophils to the area where they congregate and fight infection. A decrease in the number of neutrophils stimulates an autoimmune response which leads to arthritis. The loss and destruction of neutrophils leading to neutropenia is therefore, inflammation-driven due to the body's need for the immune response.[26]

Splenomegaly

Splenomegaly is a condition of the spleen causing it to be enlarged. The splenic condition involving Felty syndrome is more specifically noted as inflammatory splenomegaly. The spleen is an important lymphatic organ that is involved in filtration of the blood by discarding old and damaged red blood cells as well as maintaining platelet levels. The spleen is a lymphatic organ, which means it is largely involved in the immune system and immune responses. When the spleen becomes enlarged, it is a strong sign of infection somewhere in the body, and can be caused by inflammatory conditions such as rheumatoid arthritis. The increased need for production assistance of white blood cells to affected areas causes hyperfunction of the spleen. This increase in defense activities ultimately causes hypertrophy of the spleen, leading to splenomegaly.[105] The spleen is found in the left upper quadrant英语left upper quadrant (LUQ) of the peritoneal cavity and due to its enlargement, can cause stress on neighboring organs.

Diagnosis

This condition affects less than 1% of patients with rheumatoid arthritis.[106] The presence of three conditions: rheumatoid arthritis, an enlarged spleen (splenomegaly英语splenomegaly), and an abnormally low white blood cell count are indications that Felty's syndrome is possibly occurring. This condition as a whole is difficult to diagnose due to its complexity given a combination of disorders. It is commonly overlooked or misdiagnosed as other conditions (e.g., leukemia, systemic lupus erythrematosus)[25] because of the rarity and lack of good understanding about it. An acronym can be used to make recognizing this disease somewhat easier:

S: Splenomegaly

A: Anemia

N: Neutropenia

T: Thrombocytopenia

A: Arthritis (rheumatoid)

Conditions of the Blood

A complete blood count (CBC) can be done to diagnose anemia (normochromic, normocytic), thrombocytopenia英语thrombocytopenia, and neutropenia.[107] Abnormal liver function tests are commonly used to help in diagnosis as the spleen and liver are strongly affected by one another.

Splenomegaly

If rheumatoid arthritis is present and other symptoms occur that are not commonly found within RA itself, such as a palpable spleen, further testing should be done. A palpable spleen is not always a clinical significance, therefore CT scan, MRI, or ultrasound can be administered in order to help diagnose the condition. According to Poulin et al, dimensional guidelines for diagnosing splenomegaly are as follows:[108]

  • Moderate if the largest dimension is 11–20 cm
  • Severe if the largest dimension is greater than 20 cm

Rheumatoid Arthritis

RA in patients with Felty's syndrome is chronic (after 10–15 years), and presents with increased severity along with extra articular manifestations.[26] RA can be mistaken for other conditions such as gout if not clinically diagnosed. Diagnosis can be confirmed by use of X-rays or synovial fluid analysis.[109]

Treatment

There is no real treatment for Felty's syndrome, rather the best method in management of the disease is to control the underlying rheumatoid arthritis. Immunosuppressive therapy for RA often improves granulocytopenia and splenomegaly; this finding reflects the fact that Felty's syndrome is an immune-mediated disease. A major challenge in treating FS is recurring infection caused by neutropenia. Therefore, in order to decide upon and begin treatment, the cause and relationship of neutropenia with the overall condition must be well understood.[26] Most of the traditional medications used to treat RA have been used in the treatment of Felty's syndrome. No well-conducted, randomized, controlled trials support the use of any single agent. Most reports on treatment regimens involve small numbers of patients.[110]

Splenectomy英语Splenectomy may improve neutropenia in severe disease.

Use of rituximab[111] and leflunomide[112] have been proposed.

Use of gold therapy has also been described.[113][114]

幼年特发性关节炎

幼年特发性关节炎


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