Michael Corbo scite author profile

The effect of abatacept, a selective T-cell co-stimulation modulator, on vaccination has not been previously investigated. In this open-label, single-dose, randomized, parallel-group, controlled study, the effect of a single 750 mg infusion of abatacept on the antibody response to the intramuscular tetanus toxoid vaccine (primarily a memory response to a T-celldependent peptide antigen) and the intramuscular 23-valent pneumococcal vaccine (a less T-cell-dependent response to a polysaccharide antigen) was measured in 80 normal healthy volunteers. Subjects were uniformly randomized to receive one of four treatments: Group A (control group), subjects received vaccines on day 1 only; Group B, subjects received vaccines 2 weeks before abatacept; Group C, subjects received vaccines 2 weeks after abatacept; and Group D, subjects received vaccines 8 weeks after abatacept. Anti-tetanus and antipneumococcal (Danish serotypes 2, 6B, 8, 9V, 14, 19F and 23F) antibody titers were measured 14 and 28 days after vaccination. While there were no statistically significant differences between the dosing groups, geometric mean titers following tetanus or pneumococcal vaccination were generally lower in subjects who were vaccinated 2 weeks after receiving abatacept, compared with control subjects. A positive response (defined as a twofold increase in antibody titer from baseline) to tetanus vaccination at 28 days was seen, however, in ≥ 60% of subjects across all treatment groups versus 75% of control subjects. Similarly, over 70% of abatacept-treated subjects versus all control subjects (100%) responded to at least three pneumococcal serotypes, and approximately 25-30% of abatacept-treated subjects versus 45% of control subjects responded to at least six serotypes.

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Immunogenicity, Safety, and Efficacy of Abatacept Administered Subcutaneously With or Without Background Methotrexate in Patients With Rheumatoid Arthritis: Results From a Phase III, International, Multicenter, Parallel‐Arm, Open‐Label Study

Nash¹,

Nayiager²,

Genovese³

et al. 2013

Arthritis Care & Research

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Objective. To evaluate the impact of concomitant methotrexate (MTX) on subcutaneous (SC) abatacept immunogenicity, and to assess safety and efficacy.Methods. This phase III, open-label study had a 4-month short-term (ST) period and an ongoing long-term extension (LTE) period. Rheumatoid arthritis patients were stratified to receive SC abatacept (125 mg/week) with (combination) or without MTX (monotherapy), with no intravenous loading dose; patients receiving monotherapy could add MTX in the LTE period. Immunogenicity (percentage of anti-abatacept antibody-positive patients) was assessed. ST and LTE period data are reported, including efficacy through LTE month 14 and safety through LTE month 20. Results. Ninety-six of 100 enrolled patients completed the ST period; 3.9% (combination) and 4.1% of patients (monotherapy) developed transient immunogenicity, and no patients were antibody positive at month 4. Serious adverse events (SAEs) were reported in 3.9% (combination) and 6.1% of patients (monotherapy); 5.9% (combination) and 8.2% of patients (monotherapy) experienced SC injection reactions, and all were mild in intensity. Mean 28-joint Disease Activity Score (DAS28) changes were ؊1.67 (95% confidence interval [95% CI] ؊2.06, ؊1.28; combination) and ؊1.94 (95% CI ؊2.46, ؊1.42; monotherapy) at month 4. Ninety patients entered and were treated in the LTE period; 83.3% (75 of 90) remained ongoing at month 24. One LTE-treated patient (1.1%) developed immunogenicity, 14.4% of patients experienced SAEs, and no SC injection reactions were reported. For patients entering the LTE period, mean DAS28 changes from baseline were ؊1.84 (95% CI ؊2.23, ؊1.34; combination) and ؊2.86 (95% CI ؊3.46, ؊2.27; monotherapy) at month 18. Conclusion. SC abatacept did not elicit immunogenicity associated with loss of safety or efficacy, either with or without MTX.

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Targeting lymphocyte co-stimulation: From bench to bedside

et al. 2010

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T and B lymphocytes are central regulators and effectors of immune responses and are believed to have a key role in many autoimmune diseases. Targeting the activation or effector function of lymphocytes is a potentially effective approach to treat autoimmunity. Typically, T-cell activation occurs after engagement of the T-cell receptor with its cognate peptide-major histocompatibility complex (signal 1) and subsequent engagement of co-stimulatory molecules (signal 2). This "second signal" contributes to T-cell activation by promoting proliferation, survival, and effector function. In general, activation in the absence of co-stimulation leads to a reduced immune response, anergy, or even tolerance. B-cell activation similarly requires co-stimulation for the development of complete effector function. The most potent co-stimulatory molecules identified to date are CD28 for T-cells and CD40 for B-cells. Both molecules are recognized for their potential as immune modulators; however, thus far neither molecule has been successfully targeted directly for the treatment of autoimmune disease. The only current therapy to target either of these pathways is cytotoxic T-lymphocyte antigen-4 (CTLA-4-Ig), which indirectly blocks CD28 signaling and has proven efficacy in rheumatoid arthritis and juvenile idiopathic arthritis patients. In addition to CD28 and CD40, an array of other co-stimulatory as well as inhibitory pathways has recently been identified and scientists are just beginning to understand how these different signaling pathways interact to regulate lymphocyte activation. In the more than two decades since the discovery of the first co-stimulatory molecule, the full clinical potential of these pathways is yet to be realized. In this review, we will primarily focus on CD28 and CD40 which are the most clinically validated co-stimulatory pathways, and briefly summarize and discuss some of the other T-cell co-stimulatory molecules.

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A Pleiotropic Response Is Induced in F9 Embryonal Carcinoma Cells and Rhino Mouse Skin by All-trans-Retinoic Acid, a RAR Agonist but Not by SR11237, a RXR-Selective Agonist

Gendimenico¹,

Stim²,

Corbo³

et al. 1994

Journal of Investigative Dermatology

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Michael Corbo

Zinc deficiency and its management in the pediatric population: A literature review and proposed etiologic classification

Vaccination response to tetanus toxoid and 23-valent pneumococcal vaccines following administration of a single dose of abatacept: a randomized, open-label, parallel group study in healthy subjects

Immunogenicity, Safety, and Efficacy of Abatacept Administered Subcutaneously With or Without Background Methotrexate in Patients With Rheumatoid Arthritis: Results From a Phase III, International, Multicenter, Parallel‐Arm, Open‐Label Study

Targeting lymphocyte co-stimulation: From bench to bedside

A Pleiotropic Response Is Induced in F9 Embryonal Carcinoma Cells and Rhino Mouse Skin by All-trans-Retinoic Acid, a RAR Agonist but Not by SR11237, a RXR-Selective Agonist

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