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Review paper

SAPHO syndrome: pathogenesis, clinical presentation, imaging, comorbidities and treatment: a review

Hanna Przepiera-Będzak
1
,
Marek Brzosko
1

  1. Department of Rheumatology, Internal Medicine, Geriatrics and Clinical Immunology, Pomeranian Medical University, Szczecin, Poland
Adv Dermatol Allergol 2021; XXXVIII (6): 937–942
Online publish date: 2020/07/23
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- SAPHO.pdf  [0.13 MB]
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Introduction

Synovitis, acne, pustulosis, hyperostosis and osteitis (SAPHO) syndrome is a disease characterised by dermatological and osteoarticular symptoms and was introduced by Chamot et al. [1] in 1987. The diagnostic criteria for SAPHO syndrome were developed by Kahn et al. [2] in 1994.

Some authors suggest that SAPHO syndrome could be considered as a type of spondyloarthritis (SpA) or a type of psoriatic arthritis (PsA), but others maintain that these should be considered as separate diseases [3, 4].

SAPHO is more common in women than in men. The disease is predominant in middle-aged women [1, 39].

SAPHO syndrome is classified along two different spectrums: pustulo-psoriatic hyperostotic spondyloarthritis (PPHS) and chronic recurrent multifocal osteomyelitis (CRMO) [10].

The incidence of SAPHO syndrome is unknown. Most data on this syndrome come from Western and Northern Europe and from China and Japan [1, 79, 1113].

The results of our own published observations, conducted on the largest group of SAPHO patients in Poland, play a significant role in this report. Relying on our own experience, we draw attention to essential problems concerning clinical symptoms and diagnostics of SAPHO patients, which will allow for rapid diagnosis of the disease. In the treatment of SAHO we have paid attention to the possibility of using antibiotics and biological drugs.

Pathogenesis

The pathogenesis of SAPHO syndrome is unknown. Infectious, genetic, immunological and environmental factors may play a role in the development of the disease.

The role of Propionibacterium acnes antigen as a factor initiating the inflammatory process is considered, although it has been only occasionally found in bacterial cultures [1416].

Up to 30% of patients with SAPHO syndrome have been shown to be associated with the presence of the HLA-B 27 gene [4, 7].

An association has been established between copy number variations of the following genes: CSF2RA, NOD2, MEGF6, and ADAM5 and the predisposition of SAPHO syndrome [17].

Immune system dysfunction has been described in patients with SAPHO syndrome. Li et al. [18] found elevation of serum IgG4 (a subclass of immunoglobulin G) in SAPHO patients, and it correlated with activity of the disease.

Some cytokines have been considered to play a role in the pathogenesis of SAPHO. Increased serum tumour necrosis factor a (TNF-a), which plays a role in osteitis, has been observed in SAPHO patients with CRMO [19]. It has been shown that increased serum interleukin 6 (IL-6) correlated positively with C-reactive protein (CRP) and erythrocyte sedimentation ratio (ESR) in SAPHO patients [2023]. In SAPHO patients with anterior chest wall lesions, increased serum interleukin 8 (IL-8) has been observed, which suggests that this cytokine is involved in bone and joint inflammation [24]. Przepiera-Będzak et al. [25] found that increased serum levels of interleukin 18 (IL-18), and decreased serum levels of endothelin-1 (ET-1) were associated with an increased risk of palmoplantar pustulosis (PPP), characteristic skin lesion in SAPHO [25, 26]. This suggests that IL-18 and ET-1, by their influence on vasculopathy and inflammation, may play a role in the pathogenesis of skin changes in SAPHO syndrome [2426]. In another study, an increased serum level of interleukin 23 (IL-23) in SAPHO patients was shown, but it did not correlate with disease activity assessed by CRP or ESR [23]. No significant correlations were found between angiogenic cytokine levels and clinical presentation in SAPHO patients [27].

Clinical presentation

SAPHO syndrome is classified along two different spectrums (Table 1) [10]:

  1. PPHS, which is the most common form of the disease occurring in adults, consists of a triad of symptoms:

    • sternocostoclavicular hyperostosis with fibrous osteomyelitis and painful ossifying periostitis. Symptoms are usually unilateral and can lead to narrowing of the adjacent subclavian vein;

    • spondyloarthropathy with the formation of ossifying lesions in the spine, leading to the formation of syndesmophytes or parasyndesmophytes;

    • palmoplantar pustulosis (PPP), which may be accompanied by peripheral and sacroiliac arthritis.

    The course of the PPHS is mild and chronic with periods of exacerbation and remission. Skin lesion-type PPP is accompanied by symptoms of spondyloarthritis with hyperostosis.

  2. CRMO in adults, which until 1997 was only described in children, involves:

    • anterior chest wall with the involvement of the sternum and adjacent joints (50%);

    • lamellar bones (the lamellar part of the body of the bone, especially the femur) and pelvis;

    • axial skeleton, with inflammation of one or several vertebrae, or intervertebral disc and adjacent vertebral bodies (spondylodiscitis). Involvement of the jawbone results in swelling of the face.

    Skin lesions associated with CRMO include: PPP, acne, psoriasis and acne inversa [10].

Table 1

Clinical characteristics and treatment options of the synovitis acne pustulosis hyperostosis osteitis syndrome

Cutaneous manifestationsPalmoplantar pustulosis Acne fulminans or acne inversa
Osteoarticular symptoms locationPPHS:
  • Sternoclavicular joints

  • First sternocostal joints

  • Shoulder joint

  • CRMO:

  • Sternum and adjacent joints

  • Mandible

  • Lamellar bones

  • Vertebrae

Changes in imagingBone scintigraphy:
  • Increased tracer intake in the front wall of the chest

  • Computed tomography:

  • Erosions and sclerotic changes with new bone formation and hyperostosis

  • Magnetic resonance imaging:

  • Bone marrow oedema

The most common comorbiditiesAutoimmune diseases:
  • Hypothyroidism

  • Diabetes

  • Sjögren syndrome

  • Antiphospholipid syndrome

  • Depression

  • Metabolic syndrome

Treatment optionsNSAIDs
  • Antibiotics:

  • Doxycycline

  • Azithromycin

  • DMARDs:

  • MTX

  • SSZ

  • Bisphosphonates

  • Biologics:

  • TNF-α blockers

  • IL-23/IL-17 axis blockers

  • Small-molecule inhibitor of phosphodiesterase-4

[i] CRMO – chronic recurrent multifocal osteomyelitis, DMARDs – disease-modifying antirheumatic drugs, IL-23/IL-17 – interleukin 23/interleukin 17, MTX – methotrexate, NSAIDs – nonsteroidal anti-inflammatory drugs, PPHS – pustule-psoriatic hyperostotic spondyloarthritis, SSZ – sulfasalazine, TNF-α – tumor necrosis factor alpha.

In the adult form, CRMO can relapse, but remissions may persist for several years. In the course of the disease, signs of recurrent osteitis and arthritis can be observed [28].

The course of the disease is often chronic and eventually self-healing [3, 4, 6, 7, 10].

Skin changes

The typical skin lesions are PPP and severe acne (Table 1) [14, 7, 9, 11]. The pattern of skin changes could be as follows: about 80% of patients show PPP, about 5% acne and 5% no skin changes [7]. Characteristic skin changes can precede the onset of arthritis (25%) and can occur simultaneously with joint changes (63.5%) or a certain period of time after the onset of arthritis (5.8%) [7].

PPP presents in the form of yellow, sterile pustules, which are located mostly on the skin of the palmar parts of the hands and plantar parts of the feet [1, 2, 57, 10]. These pustules undergo spontaneous cracking and peeling, leaving no trace on the skin, and recurrence of skin lesions is observed. Bacteriological examination shows pustule secretion in most cases to be sterile, but in individual cases Propionibacterium acnes was cultured from the bacteriological culture of the pustule secretions [1416].

Skin changes may be preceded by or coexist with the upper respiratory tract infection (laryngitis, bronchitis, sinusitis, middle ear infection) or urinary tract infection. However, the infection is not considered to be the cause of PPP, but it can exacerbate its course. Exacerbation of skin and joint changes stimulated by chronic stress have been also reported [14, 7, 8].

Another characteristic skin change is acne fulminans or acne inversa (hidradenitis suppurativa) [29]. Usually, exacerbation of skin lesions is accompanied by exacerbation of joint symptoms [14, 79]. Single cases of other rare skin lesions in the course of SAPHO syndrome have been described in the literature, such as pyoderma gangrenosum, Sneddon-Wilkinson disease, and Sweet’s syndrome [29].

Involvement of internal organs in the course of SAPHO syndrome is rare and mainly affects soft tissues around the affected bone. There may be swelling and fibrosis of these tissues. The following organ changes have also been reported: vasoconstriction (mainly subclavian vein), pleurisy and pericarditis, ascending aortitis and enteritis [4, 30].

Joint symptoms

The first sign of arthritis is involvement of the anterior chest wall, most often the sternoclavicular joints and the first sternocostal joints, which are the areas most involved in SAPHO in up to 96% of cases. Characteristic symptoms are skin redness, oedema, palpation pain and bone hypertrophy located in the anterior chest wall, most commonly in the sternoclavicular joint [110, 24]. Shoulder joint pain and swelling (symmetrical or asymmetrical) is observed in 36.5% of patients, and small-joint arthritis in 4.5–13.5% [7, 11].

In cases with CRMO, long bone, vertebral and mandibular pain and swelling is observed [7, 10, 31].

Mandibular involvement presented as mandibular osteitis is a rare localisation of bone involvement in SAPHO syndrome and was first described by Kahn et al. [31]. Mandibular osteitis demonstrating bone sclerosis mainly involves the body of the mandible and is usually associated with a severe course of the disease [7, 3133].

In a paediatric and adult population of patients with CRMO it was observed that sternal involvement was more frequent in adults, whereas clavicle and long bone involvement was more frequent in children [28].

Laboratory findings

There is no specific laboratory test characteristic for SAPHO. Assessment of the HLA-B 27 gene is positive in up to 30% of cases [4, 7]. In laboratory tests, features of an active inflammatory process (accelerated ESR, elevated C-reactive protein) are observed [3, 4, 7, 9, 11, 19, 24].

Rheumatoid factor and anti-cyclic citrullinated peptide antibody (anti-CCP) is usually negative, although in a very small percentage of patients, it can be positive [7, 11, 24].

In about 1.9–39% of SAPHO patients, antinuclear antibodies are positive, mostly in those with the CRMO type [7, 11, 13, 19]. Also, in a small percentage of patients, a result positive for anticardiolipin antibodies was observed [7, 34].

Imaging

In addition to clinical assessment, imaging studies are important in the diagnosis of SAPHO syndrome (Table 1).

In early stages of the disease, bone scintigraphy is useful, and approximately 85–95% of patients have an increased tracer intake in the front wall of the chest, indicating an inflammatory process of the skeleton [3, 7, 12, 35, 36]. Changes are unilateral or bilateral in the area of the sternoclavicular, costochondral and costosternal joints [7, 12, 3639]. However, not all patients who reported pain in the sternoclavicular joints show scintigraphic changes in this area. It should also be remembered that the result of a scintigraphic examination in the diagnosis of skeletal inflammatory changes may be unspecific [7, 12, 35, 36, 39].

Routine radiographic images of bones and joints present abnormalities in up to 26% of patients, most frequently as subchondral sclerosis in association with periosteal new bone formation. Erosions are observed much less frequently, in only 12% of patients with peripheral arthritis, and are most often associated with sclerosis. Conventional radiographs of the sternocostoclavicular region show subchondral sclerosis and erosions with associated enthesopathy. Changes are usually asymmetrical [3, 4, 7, 12]. In patients with a short duration of the disease, the radiological image may be normal [7, 35, 3942].

On computed tomography (CT) examination, erosions and sclerotic changes with new bone formation and hyperostosis are observed in up to 45% of patients [9, 36, 3840]. The ligamentous ossifications are usually delicate [9]. In addition, the CT scans are useful in differentiating changes in the course of SAPHO syndrome with other disorders such as neoplasm [10, 31].

Magnetic resonance imaging (MRI) is useful in cases with CRMO and presents as bone marrow oedema in mandible, vertebral or lamellar bone [7, 12, 13, 31]. In 89% of cases, sacroiliitis is observed in MRI assessment [13].

Diagnosis and differential diagnoses

The diagnosis of SAPHO syndrome is based on fulfilling at least one of the criteria described by Kahn et al. [2], which include: 1) chronic recurrent multifocal osteomyelitis, usually sterile, spine may be involved, with or without skin lesions, 2) acute, subacute or chronic arthritis associated with any of the following: PPP, pustular psoriasis or severe acne, and 3) any sterile osteitis associated with any of the following: PPP, pustular psoriasis, psoriasis vulgaris or severe acne.

The differential diagnoses of SAPHO syndrome include infectious neoplasm and other bone abnormalities such as: infectious osteomyelitis, infectious spondylodiscitis, osteosarcoma, Ewing sarcoma, bony metastasis, Paget’s disease, eosinophilic granuloma, osteoarthritis and osteonecrosis. The biopsy of bone lesions with the assessment of histopathological changes and bacterial cultures are helpful to exclude bone neoplasms or infectious osteomyelitis [10, 31].

Comorbidities

There is not much known about the comorbidities in the course of SAPHO (Table 1).

An increased prevalence of autoimmune diseases in patients with SAPHO syndrome has been reported [7, 19, 43]. In a study by Przepiera-Będzak et al. [7], the most common comorbidities were hypothyroidism and diabetes. One patient had Sjögren syndrome, and one antiphospholipid syndrome. This could confirm the suggestion that autoimmunity may play a role in the pathomechanism of SAPHO syndrome [7, 19, 34, 43].

In a study by Hayem et al. [4], inflammatory bowel disease, mostly Crohn’s disease, was observed in 7.5% of patients; this coincidence, on the other hand, is characteristic of spondyloarthritis.

SAPHO patients have higher BMI than healthy controls and 19.5% of them meet criteria for metabolic syndrome (MetS). Disease activity correlates positively with levels of total cholesterol (TC) and LDL-cholesterol (LDL-C), which are well-known markers of the risk of cardiovascular disease. This suggests an increased risk of cardiovascular disease in this group of patients. Increased triglyceride (TG) and LDL-C levels and an increased prevalence of MetS in SAPHO patients treated with methotrexate (MTX) could suggest that in SAPHO patients MTX treatment promotes or exacerbates MetS [44].

It was reported that patients with psoriasis and PsA have an increased risk of depression [45, 46]. Przepiera-Będzak et al. [7] observed a high prevalence of depression in SAPHO patients. Patients suffered from a cosmetic disability caused by active PPP, and skin changes negatively affected their interpersonal contacts. This could suggest that SAPHO patients have an increased risk of depression. Effective treatment of skin lesions would have a beneficial effect on their quality of life [7].

Treatment

As the cause of SAPHO is unknown, there are no standard recommendations for treatment (Table 1).

Usually, the first-line drugs are nonsteroidal anti-inflammatory drugs (NSAIDs). These drugs could reduce the joint symptoms, but have no influence on skin changes. NSAIDs are effective in only some patients [3, 4, 7, 9].

As Propionibacterium acnes is considered to be an important trigger of SAPHO syndrome, antibiotics are also useful in its treatment. Antibiotics such as doxycycline or azithromycin showed a good response in patients with active skin changes [7, 1416].

There are data presented that the use of disease-modifying antirheumatic drugs (DMARDs), particularly MTX and sulfasalazine (SSZ), has been effective in some patients [4, 7, 9]. Przepiera-Będzak et al. [7] observed good response in some patients to SSZ treatment, but in others they had to switch to MTX. In patients with mandibular osteomyelitis, glucocorticosteroids (GCS) can be considered [31].

Bisphosphonates may lead to remission in up to 73% of patients with CRMO after failure of NSAID and GCS therapy, especially in patients with vertebral involvement [47]. The safety of their use has been discussed. To date, no cases of osteonecrosis of the jaw have been reported in paediatric CRMO patients. Oral alendronate has been shown to be effective in treating refractory SAPHO-syndrome-type CRMO with femoral involvement [48]. In a study of 11 patients (9 F; 2 M) on SAPHO-type CRMO with mandibular involvement, a single infusion of ibandronate (6 mg i.v.) was effective in reducing pain in 7 patients, and in 4 patients two infusions of ibandronate were administered, resulting in a reduction of clinical symptoms and changes on scintigraphic examination [49].

The use of biologics in SAPHO could be effective in patients not responding to conventional treatment. There are data of successful treatment with TNF-a blockers. Infliximab was most commonly used in patients with SAPHO, mostly at a dose of 5 mg/kg. Dramatic improvement in joint pain and swelling symptoms was observed; however, in some cases an exacerbation of the skin disease was present [5054]. There are data on a small number of cases concerning etanercept, adalimumab and certolizumab pegol treatment in SAPHO patients. The treatment was well tolerated, and clinical improvement was observed concerning joints, skin symptoms and mandibular osteomyelitis [5558]. There are extremely limited data suggesting that interleukin 1 (IL-1) inhibition with anakinra does not seem effective in controlling skin disease in SAPHO patients [59, 60]. Data regarding the use of newer biologics targeting the IL-23/IL-17 axis in patients with SAPHO are limited. The effectiveness of ustekinumab or secukinumab range from 40% to 60% [61].

There are little data concerning apremilast, an orally available small-molecule inhibitor of phosphodiesterase-4, which has been used successfully in the treatment of psoriasis and psoriatic arthritis [62].

Although IL-6 inhibition appears ineffective in SpA, adult-onset CRMO cases successfully treated with tocilizumab have been reported [63].

The SAPHO syndrome is a rare but very interesting problem. Knowledge of its characteristic symptoms and diagnostic procedures may increase the frequency of its early diagnosis and prevent osteoarticular progression. In addition, co-operation between rheumatologists and dermatologists will improve the quality of life for SAPHO patients.

Conflict of interest

The authors declare no conflict of interest.

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