Medical Treatment of Graves' Orbitopathy.

The medical treatment of Graves' orbitopathy (GO) is usually reserved to moderate to severe disease. Steroids have been widely employed and possess anti-inflammatory activity, but about 20-30% of patients are not responsive and about 20% present with disease recurrence. Immunosuppressive therapy alternative to corticosteroids may target the different antigens involved in pathogenic mechanisms of GO. Some have already been employed in clinical studies and showed interesting results, although the lack of randomized and controlled trials suggests caution for their use in clinical practice. Potential targets for therapy in GO are the TSH receptor and the IGF-1 receptor on the fibroblasts, inflammatory cytokines, B and T cells. Most promising results are obtained by interacting with the PIK3/mTORC1 signaling cascades for adipogenesis and the anti-IGF-1R with the monoclonal antibody teprotumumab. A recent open study has shown that tocilizumab, an anti-sIL-6R antibody, inactivates GO. Consistent reports on the efficacy of rituximab have recently been challenged by randomized controlled trials. Clinical practice will greatly benefit from the use of disease modifying agents in GO, as compared to steroids, currently standard treatment for GO. Among these, rituximab may be useful, especially in patients resistant to steroid or with contraindications to steroids. However, larger randomized controlled trials are needed for definitive data on the potential disease-modifying role of rituximab in GO. Direct targeting of the orbital fibroblast via immunosuppression or nonimmunosuppressive drugs is emerging as a promising alternative.

The IGSF1 deficiency syndrome: characteristics of male and female patients.

CONTEXT: Ig superfamily member 1 (IGSF1) deficiency was recently discovered as a novel X-linked cause of central hypothyroidism (CeH) and macro-orchidism. However, clinical and biochemical data regarding growth, puberty, and metabolic outcome, as well as features of female carriers, are scarce. OBJECTIVE: Our objective was to investigate clinical and biochemical characteristics associated with IGSF1 deficiency in both sexes. METHODS: All patients (n = 42, 24 males) from 10 families examined in the university clinics of Leiden, Amsterdam, Cambridge, and Milan were included in this case series. Detailed clinical data were collected with an identical protocol, and biochemical measurements were performed in a central laboratory. RESULTS: Male patients (age 0-87 years, 17 index cases and 7 from family studies) showed CeH (100%), hypoprolactinemia (n = 16, 67%), and transient partial GH deficiency (n = 3, 13%). Pubertal testosterone production was delayed, as were the growth spurt and pubic hair development. However, testicular growth started at a normal age and attained macro-orchid size in all evaluable adults. Body mass index, percent fat, and waist circumference tended to be elevated. The metabolic syndrome was present in 4 of 5 patients over 55 years of age. Heterozygous female carriers (age 32-80 years) showed CeH in 6 of 18 cases (33%), hypoprolactinemia in 2 (11%), and GH deficiency in none. As in men, body mass index, percent fat, and waist circumference were relatively high, and the metabolic syndrome was present in 3 cases. CONCLUSION: In male patients, the X-linked IGSF1 deficiency syndrome is characterized by CeH, hypoprolactinemia, delayed puberty, macro-orchidism, and increased body weight. A subset of female carriers also exhibits CeH.

Rituximab treatment in patients with active Graves' orbitopathy: effects on proinflammatory and humoral immune reactions.

In active Graves' orbitopathy (GO), proinflammatory cytokines predominate. Circulating thyroid stimulating hormone (TSH)-receptor antibodies (TRAb) have been correlated with GO clinical activity and severity. In preliminary studies rituximab (RTX), an anti-CD 20 monoclonal antibody, has induced clinical improvement of active GO without a change in serum anti-thyroid antibodies. We have studied whether RTX in GO acts by affecting proinflammatory cytokines and thyroid and orbital-directed antibodies. Ten patients with GO were treated with RTX, administered twice intravenously (i.v.) (1000 mg) at days 1 and 15, and 20 with methylprednisolone, administered weekly i.v. (500 mg), for 16 weeks. Patients were studied before treatment, at B cell depletion and at 4, 8, 16, 20, 30 and 50 weeks. Peripheral lymphocytes, serum interleukin (sIL)-6, sIL-6r, chemokine (C-X-C motif) ligand 10 (CXCL10), TRAb and stimulating antibodies (TSAb) and autoantibodies against orbital calsequestrin, collagen XIII and flavoprotein subunit of succinate dehydrogenase (FP-SDH) were measured at baseline and after treatment. Serum IL-6 and sIL-6R concentrations did not change after RTX [P = not significant (n.s.)]. Serum CXCL10 increased after RTX at B cell depletion and at 30 weeks (P < 0·003). Serum TSAb did not change in relation to TRAb, nor did antibodies against orbital antigens (P = n.s.). In conclusion, this study shows that RTX in GO does not affect humoral reactions. The observed increase of serum CXCL10 concentrations at B cell depletion may result from cell lysis. We suggest that RTX may exert its effect in GO by inhibiting B cell antigen presentation.

Graves' orbitopathy activation after radioactive iodine therapy with and without steroid prophylaxis.

CONTEXT: The reactivation of Graves' orbitopathy (GO) after radioiodine (RAI) for Graves' disease (GD) is a known effect, and its clinical relevance is controversial. Prevention of RAI-induced GO activation is possible in at-risk patients with oral glucocorticoids (OGC). OBJECTIVES: The aim of the study was to analyze the effects of RAI on GO with or without prophylactic steroids based on known risk factors and to compare the effectiveness of prophylaxis with iv glucocorticoids (IVGC) and OGC. DESIGN: We conducted a retrospective study in which patients were assessed before and 1-12 months after RAI. PATIENTS AND SETTING: A total of 113 patients were included in the study; 83 underwent RAI without prophylactic steroids for the absence of risk of activation, and 30 were treated with either OGC (n = 21) or IVGC (n = 9). MAIN OUTCOME MEASURES: We analyzed the prevalence of GO activation with or without steroid prophylaxis and the difference in the prevalence of GO activation after OGC or IVGC. RESULTS: GO activation was observed in 7.2% of patients without and 33.3% of patients with steroid prophylaxis (P < 0.0001), for an overall prevalence of 14.6%. GO activation occurred in 47.6% of patients treated with OGC but in none of the nine patients treated with IVGC (P = 0.0001). Disease activation was more prevalent in males (P < 0.02) and in older patients (P = 0.04) with a shorter duration of GD (P < 0.01) and time from GO onset (P < 0.01). CONCLUSIONS: GO may occur after RAI in approximately 15% of patients also in the absence of signs of active GO. Prophylactic OGC did not prevent GO activation in a large proportion of patients, compared to IVGC.

New immunomodulators in the treatment of Graves' ophthalmopathy.

Steroids have been used in the therapy of the moderate to severe forms of Graves' ophthalmopathy (GO) and other autoimmune diseases as they act only as general immunosuppressants. Previous work has shown that blocking the CD-20 receptor on B lymphocytes has significantly affected the clinical course of GO, by rapidly reducing inflammation and the degree of proptosis. We have studied nine patients with Graves' disease, of whom seven had active GO and two, with newly diagnosed hyperthyroidism, only mild lid signs. We also studied a group of 20 consecutive patients, treated with intravenous glucocorticoids (IVGC) according to a standard protocol. Patients treated with RTX (1000mg i.v. twice at two-week interval) and those treated with IVGC (500mg i.v. for 16 weeks) were studied monthly up to 12 months after the first drug infusion. By ophthalmological examination, GO was assessed by the clinical activity score (CAS) and by the NOSPECS score. Thyroid function and lymphocyte count were measured by standardized methods. RTX was well-tolerated and only minor side-effects were reported in 30% of patients during the first infusion. All patients attained peripheral B-cell depletion with the first RTX infusion. All but one patients showed both CD20+ cells and CD19+ cells depletion, while one had persistent 3-5% CD19+ cells in the periphery, mostly CD19+5+. Thyroid function was not affected by RTX therapy. Titers of antithyroglobulin (TgAb), antithyroperoxidase and anti-TSH receptor antibodies (TRAb) did not change significantly (P=NS) and did not correlate to CD20+ depletion (P=NS). CAS values decreased significantly (P<0.0001). Proptosis decreased significantly after RTX in both patients with active GO (ANOVA; P<0.0001) and in those with Graves' hyperthyroidism and lid signs (ANOVA; P<0.003). The degree of inflammation (NOSPECS class 2) decreased significantly in response to RTX (ANOVA; P<0.001). In patients treated with IVGC, mean CAS value decreased significantly less than in those treated with RTX (P<0.05). Adverse effects were more frequent after IVGC (45% of patients). Seventy-five percent of patients responded to IVGC and 10% showed relapse of active GO six to eight weeks after withdrawal. The results of this study on RTX in GO suggest that the drug is effective in modifying the disease course and that the improvement of the clinical activity of GO after RTX was more significant than after IVGC. We did not observe relapse of active GO, even after B-cell return in peripheral blood. This might be related to the persistence of a significant degree of B-cell depletion after RTX observed in the peripheral blood as late as two years of follow-up. RTX therapy was also effective in improving proptosis and soft tissue inflammation. The mechanism by which RTX affects GO is unknown. It may act as a true immunosuppressor by switching off reactions inducing the active phase of TAO, perhaps by influencing the cytokine production in the orbit or by inducing depletion of antigen presenting B-cells.

Rituximab induces distinct intraorbital and intrathyroidal effects in one patient satisfactorily treated for Graves' ophthalmopathy.

Hyperthyroid Graves' disease (GD) is a B-cell-mediated disease caused by antibodies stimulating the thyroid stimulating hormone (TSH) receptor (TRAb). A proportion of patients (40-60%) present with an associated ophthalmopathy (TAO), a progressive inflammatory autoimmune disease of the retroorbital tissue. We thought that the anti-CD20 monoclonal antibody rituximab (RTX), by inducing transient B-cell depletion, may potentially modify the active inflammatory phase of TAO. One patient with GD and TAO in its active phase and unresponsive to steroid, was treated with RTX. Whereas the ophthalmopathy responded to RTX therapy and a decrease in the clinical activity score from 5 to 2 was observed during the B-cell depletion, serum antithyroid antibodies, and in particular serum TRAb, were not affected by therapy. When the patient underwent total thyroidectomy, we found B-cells in the thyroid tissue specimens. The eye disease remained stable (clinical activity score=2) and the patient subsequently underwent orbital decompression to correct proptosis of the eye. At that time we did not find lymphocytes in any of the orbital tissue specimens. We believe that RTX therapy in GD may cause amelioration of ophthalmopathy by depleting total lymphocyte population in the orbit, but not lymphocyte depletion in thyroid tissue with consequent unchanged serum TRAb levels.