Results
After 3 months of rituximab treatment, this patient was seen at the outpatient clinic of internal medicine for hypothyroidism and diabetes. At that time there were no complaints of palpitations or weight loss. Remarkably, blood test results showed decreased TSH levels (0.24 mU/L), with a FT₄ level in the high-normal range. After 5 and 6 months of treatment there was only a slight improvement of her active RA status, but blood test results revealed clinical hyperthyroidism (TSH, 0.10 mU/L; FT₄, 25 pmol/L, and total triiodothyronine [T₃], 3.1 nmol/L [to convert to nanograms per liter, divide by 0.0154] [reference range, 1.2-2.8 nmol/L]) (Figure, A). Both T₃ and FT₄ levels were elevated, indicating that the conversion of thyroxine in T₃ was proceeding accurately. Differential diagnostic considerations explaining the development of hyperthyroidism can be divided intoexogenous (eg, pituitary TSH production) and endogenous (eg, Graves disease) causes. Both exogenous (as TSH levels were decreased, with inflated thyroxine levels), and endogenous (such as Graves disease) causes of hyperthyroidism seemed unlikely in this long-standing overt hypothyroid patient. Neither the L-thyroxine dosage nor smoking habits were changed, and the patient's type 1 diabetes mellitus remained in a well-controlled condition (hemoglobin A_1c level of 6.5%). Another mechanism that may explain the incidence of hyperthyroidism is an increased activation of thyroid peroxidase (TPO), an enzyme catalyzing reactions for synthesis of T₃ and FT₄. A plausible explanation for elevated TPO activity is a drop in the level of antibodies against TPO (TPOAbs) by rituximab-induced depletion of plasma cell precursors. Indeed, TPOAbs declined to undetectable levels (as measured with the Phadia ImmunoCAP System; Phadia AB, Phadia AB, Uppsala, Sweden) after 5 months of treatment (Figure, A).

View larger version (28K): [in this window] [in a new window] [as a PowerPoint slide]   Figure. Thyroid function during 9 months of rituximab therapy. FT4 indicates free thyroxine; TPOAbs, antibodies against thyroid peroxidase; and TSH, thyrotropin. To convert FT4 to nanograms per liter, divide by 12.871.

Comment
Autoimmune hypothyroidism is characterized by lymphocytic infiltration of the thyroid and the presence of thyroid autoantibodies (eg, TPOAbs).¹ Another autoimmune disease characterized by (synovial) lymphocytic infiltration is RA. Rituximab, a chimeric monoclonal antibody against CD20-positive B lymphocytes, is known to decrease synovial lymphocyte aggregates in patients with RA.² Our hypothyroid diabetic patient with RA developed hyperthyroidism 4 months after initiating rituximab therapy. This is remarkable because rituximab is a novel therapy for patients with Graves disease.³ Interestingly, in NOD.H-2h4 mice exposed to sodium iodide–polluted water to induce spontaneous autoimmune thyroiditis, thyroid autoantibody responses could be reduced by B-cell depletion. Moreover, B-lymphocyte depletion in this murine study resulted in diminished B- and T-lymphocyte infiltration of the thyroid, thereby inhibiting the development of spontaneous autoimmune thyroiditis.⁴ In line with this study, our observation suggests that rituximab therapy may be beneficial for autoimmune hypothyroidism. Although this hypothesis needs confirmation in other studies, in daily clinical practice, clinicians should be aware of (transient) stimulation of thyroid function during rituximab therapy in overt hypothyroid patients.

AUTHOR INFORMATION
Correspondence: Dr Nurmohamed, Departments of Internal Medicine and Rheumatology, VU University Medical Centre, PO Box 7057, 1007 MB Amsterdam, the Netherlands (mt.nurmohamed{at}vumc.nl).

Author Contributions: Study concept and design: Raterman, Simsek, and Nurmohamed. Acquisition of data: Raterman, Simsek, and Meesters. Analysis and interpretation of data: Raterman, Simsek, Lems, Meesters, Dijkmans, and Nurmohamed. Drafting of the manuscript: Raterman, Lems, and Nurmohamed. Critical revision of the manuscript for important intellectual content: Simsek, Lems, Meesters, Dijkmans, and Nurmohamed. Obtained funding: Dijkmans. Study supervision: Simsek, Lems, Dijkmans, and Nurmohamed.

Financial Disclosure: Dr Dijkmans has received an educational grant from Roche Nederland.