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S Afr Fam Pract
ISSN 2078-6190    EISSN 2078-6204 

© 2016 The Author(s)

REVIEW

Introduction

The arthritic diseases are progressive and debilitating and 
impair the quality of life of patients. It is now common practice 
to use disease modifying agents early after a diagnosis is 
made to prevent irreversible joint damage. In recent years the 
biological DMARDS have been proven to be efficacious against 
the progression of rheumatoid arthritis (RA) when there is 
no response or a poor response to traditional DMARDs.1,2 An 
overview of the biological disease modifying agents available for 
use in South Africa is provided here. 

The biological DMARDS are effective when used as single 
agents but they are seldom used alone, since combinations 
with methotrexate have been shown to have clinical benefit.2 

Methotrexate use prevents the formation of antibodies to the 
biological agents, which extends their therapeutic lifespan. 

The prohibitive cost of the biological agents and their cost-
effectiveness remains an ongoing debate. In this context a 
recent Cochrane review indicates that methotrexate based small 
molecule triple therapy may be as efficacious as combinations of 
biological DMARDs with methotrexate.3

What are biological agents?

Biological DMARDs are protein molecules and include 
monoclonal antibodies and antibody based fusion proteins. 
Monoclonal antibodies bind to a specific molecular target, 
causing inactivation of the target and compete with the natural 
ligand for binding to the target, thereby preventing the function 
of the target molecule. Once a monoclonal antibody has 
associated with its target it triggers the antibody dependent 
cellular cytotoxic immune response and/or the complement 
system causing the removal/destruction of the target by the 

Abstract

The past decade has seen a major change in the treatment options and strategies for rheumatoid arthritis (RA) and the other 
immune-mediated arthritic diseases. The disease modifying antirheumatic drugs (DMARDs) are now used in early stages of the 
disease in order to preserve joint architecture. There are two groups of DMARDs, the small molecules, like methotrexate, and 
the biological DMARDs, which are frequently referred to as “magic bullets” since they target specific cytokines and immune cells 
associated with arthritic conditions.  They are monoclonal antibodies or fusion proteins designed to bind and inactivate immune 
targets.

Tumour necrosis factor-alpha (TNF-α) plays an important role in the pathogenesis of rheumatoid disorders and is the target of 
four biological DMARDs, etanercept, infliximab, golimumab and adalimumab. The other biological DMARDs include abatacept, 
rituximab and tocilizumab and these prevent T-cell costimulation, cause the depletion of mature CD20 positive B cells or prevent 
the activation of the interleukin-6 receptor molecule, respectively. Ustekinumab, a monoclonal antibody against IL12/IL23 is 
effective in psoriatic arthritis.

Biological agents are indicated when patients do not respond adequately to the traditional DMARDs. Numerous clinical trials 
have shown that the biological agents reduce joint inflammation and erosive damage, especially when used in combination with 
methotrexate. 

Apart from their prohibitive cost, the biological agents are not without potentially serious adverse effects with infections being the 
main concern. The TNF-α inhibitors increase the risk for tuberculosis and other opportunistic infections, whereas the non-TNF-α 
immune inhibitors increase the risk for opportunistic viral, fungal and bacterial infections. This review provides an overview of the 
biological agents currently available in South Africa.

Keywords: TNF-α inhibitors, non-TNF-α biological agents, anti-rheumatic drugs, monoclonal antibodies, fusion proteins, immune 
modulators

South African Family Practice 2016; 58(6):6-10
 
Open Access article distributed under the terms of the 
Creative Commons License [CC BY-NC-ND 4.0] 
http://creativecommons.org/licenses/by-nc-nd/4.0

An overview of the biological disease modifying drugs available for arthritic 
conditions in South Africa
Leonie Harmse,a* Helmuth Reuterb 

aPharmacology Division, School of Therapeutic Sciences, Faculty of Health Sciences, University of the Witwatersrand
bDivision of Clinical Pharmacology, Faculty of Medicine and Health Sciences, Stellenbosch University

*Corresponding author, email: leonie.harmse@wits.ac.za



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immune system as shown in Figure 1. In the treatment of 
the arthritis group of diseases there are two main groups of 
biological agents available, the tumour necrosis factor-α (TNF-α) 
inhibitors and the non-TNF-α inhibitors of the immune system.

TNF-α as a drug target

TNF-α, a pro-inflammatory cytokine, was identified by Brennan 
et al in 1989 as an important target molecule in the inflamed 
synovium of rheumatoid arthritis patients.4 Since then clinical 
trials have proven that a decrease in circulating TNF-α levels 
decrease disease severity and preserve joint architecture in RA. 
Clinical trials proved TNF-α inhibitors to have equal efficacy to 
methotrexate when used alone and superior efficacy when used 
in combination with methotrexate. In addition, the combined use 
of TNF-α inhibitors and methotrexate prevents the formation of 
antibodies to the TNF-α inhibitors. The available TNF-α inhibitors 
bind to both soluble and membrane bound TNF-α.2,4

Adverse effects associated with TNF-α inhibitors are associated 
with the role of TNF-α in the immune system.  Of particular 
concern is the increased risk of infections, especially with 
organisms causing the formation of granulomas, like tuberculosis 
(TB) and histoplasmosis. In South Africa, the high TB burden 
makes it imperative to screen patients for latent and active 
infections prior to initiation of TNF-α therapy. It is advisable to 
immunize prospective patients against influenza, varicella zoster 
and pneumococcal disease.1 In addition, there is an increased 
risk for fungal viral and other bacterial infections. As with any 
immunosuppressive regimen, there is always a potential for 
the development of a malignancy, and patients require careful 
monitoring.5,6 

The use of TNF-α inhibitors has been associated with a spectrum 
of cutaneous reactions. Skin lesions range from injection site 
reactions to infections that are directly related to immune 
suppression, like bacterial cellulitis and Herpes zoster. Skin 
neoplasms and a host of immune mediated cutaneous diseases 
ranging from psoriasis to vasculitis and pemphigus are associated 
with TNF-α inhibition.7

TNF-α is secreted by monocytes, macrophages, T cells, B cells and 

fibroblasts and is important to the normal immune response. It is 

essential for both the formation and maintenance of granulomas 

in mycobacterial infections, explaining why latent infections 

are reactivated in patients treated with TNF-α inhibitors. TNF-α 

functions as a growth factor, induces the formation of pro-

inflammatory cytokines and endothelial adhesion molecules 

needed for leucocyte accumulation in tissues. TNF-α is essential 

for the defence against intracellular pathogens and functions as 

a co-mitogen for T and B cells.8

On a molecular level, TNF-α causes the trimerization of TNF-α 

receptors which activates signal transduction cascades that 

trigger apoptosis and orchestrate the translocation of the 

transcription factors AP-1 and NF-κB to the cell nucleus, as 
shown in Figure 2. AP-1 and NF-κB stimulate the transcription 
of numerous cytokine genes involved in the immune response.8 

TNF-α inhibitors

Etanercept

Etanercept is a recombinant fusion protein consisting of the 

TNF-α p75 receptor dimerized on the Fc portion of human IgG1. 

The TNF-α p75 region binds to soluble and membrane bound 

TNF-α. The presence of mouse amino-acid sequences induces 

an antibody response that decreases it function, therefore co-

administration of methotrexate is desirable.2,9

Etanercept use is associated with an increased risk for bacterial 

infections and septic arthritis. Compared to the other TNF-α 

inhibitors, reactivation of tuberculosis is less frequent with 

etanercept. The formation of anti-nuclear antibodies has been 

Figure 1. A summary of the consequences of monoclonal antibody 
binding to its specific receptor molecules. R: antibody specific receptor, 
McAB: monoclonal antibody, Fc: receptor binding to constant region of 
a monoclonal antibody, ADCC: antibody dependent cellular cytotoxicity

Figure 2. The multiple roles of TNF-α in the immune response. 
TNF-α forms a trimeric molecule which initiates the trimerization of 
its receptor molecules. This stimulates signal transduction cascades 
which result in the translocation of cytoplasmic transcription factors 
like NF-κB and AP-1 to the nucleus. In the nucleus, this causes the 
transcription of more inflammatory and pro-inflammatory cytokine 
genes. It also induces the expression of endothelial adhesion proteins 
and chemokines in the synovium which attracts leucocytes to the 
synovium. In addition, activation of the receptor can cause apoptosis in 
cells harbouring intracellular pathogens.



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reported with etanercept, but unless active lupus develops, 
cessation of treatment is not indicated.2,6

Infliximab 

Infliximab is an older generation chimeric human/mouse 
monoclonal antibody and binds soluble and membrane-
associated TNF-α receptors.  Concurrent administration with 
methotrexate or glucocorticosteroids reduces formation of anti-
chimeric antibodies and is recommended.2,6

Golimumab 

This is a humanized monoclonal antibody reducing the risk 
of antibody formation and has a high affinity for soluble and 
membrane bound TNF-α. Adverse effects are associated with the 
inhibition of TNF-α. It is used in moderate to severe rheumatoid 
arthritis in adults.2,6

Adalimumab

Adalimumab is a human IgG1 monoclonal antibody to TNF-α. It 
forms a complex with soluble TNF-α and prevents its interaction 
with TNFα p55 and p75 cell surface receptors. The use of 
adalimumab decreases macrophage and T-cell function.2,6

Non-TNF-α biological immune modulators

Currently, four non-TNF-α biological molecules are available 
to use in the arthritic diseases. Abatacept, rituximab and 
tocilizumab are used in the management of rheumatoid arthritis. 
Ustekinumab is a new monoclonal antibody and is active against 
psoriatic arthritis and psoriasis but not against rheumatoid 
arthritis.5

Abatacept 

Abatacept is a genetically engineered fusion protein consisting 
of the extracellular domain of cytotoxic T-lymphocyte-associated 
antigen (CTLA-4) fused to the hinge region of IgG1. The activation 
of naïve T cells requires the CD80/86 costimulatory molecules on 
dendritic cells to interact with the CD28 molecule on naïve T cells. 
This interaction is required to complete antigen presentation. 
Abatacept blocks T-cell costimulation by preventing the binding 

of CD80/86 to CD28 as shown in Figure 3. This decreases the 

response of naïve T cells to antigen presentation.2,10 

Abatacept is used in both TNF-α naïve patients and in patients 

who have previously failed on TNF-α therapy.6,11 Concurrent 

administration with TNF-α inhibitors is discouraged. Abatacept 

increases the risk for re-activation of latent TB and increases the 

risk for upper respiratory tract infections. Infusion reactions are 

rare.

Rituximab 

Rituximab is a chimeric monoclonal antibody to the CD20 

receptor found on mature B lymphocytes. Its use leads to the 

long-lasting near depletion of B cells in the peripheral blood. 

Rituximab is not used exclusively for the treatment of rheumatoid 

arthritis but also treat cancers like lymphoma. Rituximab is 

indicated in rheumatoid arthritis when patients fail to respond to 

TNF-α inhibitors.12,13 Cell mediated and complement dependent 

cytotoxicity and apoptosis are responsible for the depletion of B 

lymphocytes.

Table 1: TNF-α inhibitors kinetics and indications

TNF-α Inhibitor T½ (Days) Dose and interval Indications

Etanercept (Enbrel) 4.5 25 mg twice weekly  
          or
50 mg once weekly
Subcutaneous

Rheumatoid arthritis,
Psoriasis,
Ankylosing spondylitis,
Juvenile chronic arthritis

Infliximab (Revellex) 9–12 3- 5 mg/kg every 4–8 weeks
Subcutaneous

Rheumatoid arthritis,
Psoriasis,
Ankylosing spondylitis 

Golimumab (Simponi) 14 50 mg/month
Subcutaneous

Rheumatoid arthritis,
Psoriatic arthritis,
Ankylosing spondylitis

Adalimumab (Humira) 10–12 80 mg loading dose,
thereafter 40 mg every 14–20 days
Subcutaneous

Rheumatoid arthritis,
Ankylosing spondylitis, 
Psoriatic arthritis,
Juvenile idiopathic arthritis, 
Plaque psoriasis, 
Crohn’s disease

Figure 3. A schematic diagram showing the binding of abatacept to 
CD80/86 and preventing its interaction with CD28 on naïve T-cells. APC: 
antigen presenting cell; MHC: major histocompatibility complex, TCR: 
T-cell receptor, Ag: antigen, CD28: receptor molecule for CD80/86



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The high dose of rituximab causes an infusion reaction which 
can be managed by pre-treatment with a glucocorticosteroid. 
A skin rash is common with the first treatment but decreases 
with subsequent treatments. In the case of an urticarial rash 
or an anaphylactic reaction, the use of rituximab should be 
discontinued. Rituximab is not associated with the reactivation 
of TB infections, lymphomas or other tumours. However, 
the reactivation of hepatitis B is a concern and concomitant 
antiviral therapy is recommended. Although rare, multifocal 
leukoencephalopathy is a serious adverse reaction associated 
with rituximab.14

Tocilizumab 

Tocilizumab is a humanized monoclonal antibody that binds 
to soluble and membrane bound IL-6 receptors, preventing 
IL-6 mediated signalling. Interleukin 6 is produced by various 
immune cells, including macrophages and fibroblasts, and is 
recognized as an important pro-inflammatory cytokine. IL-6 
regulates T-cell function, the acute phase reaction and terminal 
B-cell differentiation. Binding of IL-6 causes the recruitment of 
two molecules of glycoprotein 130 (gp130) to the receptor.15 The 
IL-6 receptor is expressed on hepatocytes and a subpopulation 
of leucocytes and megakaryocytes. 15

IL-6 combined with transforming growth factor β induces the 
differentiation of naïve T cells to inflammatory Th17 cells. This 
promotes the maturation of B cells toward the production of 
IgG.  In hepatocytes it stimulates the production of acute phase 
reactants like C-reactive protein, serum amyloid A, haptoglobin, 
fibrinogen and α-anti-chymotrypsin. In addition, it decreases the 
hepatic production of transferrin and hepcidin, contributing to 
anaemia of chronic inflammation.15

Used therapeutically, tocilizumab decreases rheumatoid factor, 
acute phase reactants and inflammatory Th17 cells, and reduces 
bone resorption. However, tocilizumab is associated with several 

adverse drug reactions shown in Table 2 and is not recommended 
for patients with hepatic disease.

Ustekinumab

This monoclonal antibody inhibits the function of IL12/IL23 
and is registered in South Africa for the treatment of psoriasis. 
It is effective in treating psoriatic arthritis, psoriasis and Crohn’s 
disease, but has no clinical benefit in rheumatoid arthritis.16 

Ustekinumab binds to the p40 subunit of both IL-12 and IL-23 
and prevents them binding to their respective receptors. IL-12 
is produced by macrophages and promotes the Th1 response, 
activates natural killer cells and together with IL-18 causes 
interferon-γ release.16 The failure of ustekinumab in rheumatoid 
arthritis indicates that these processes are not important in the 
pathogenesis of rheumatoid arthritis. 

Summary of key concepts in the use therapeutic use 
of biological DMARDs

• Biological DMARDs are indicated when therapy with small 
molecule DMARDs fails. 

• Biological agents can be used with or without methotrexate, 
but methotrexate prolongs the therapeutic lifespan of the 
biological agents.

• TNF-α inhibitors are used before the non-TNF-α inhibitors.

• Tuberculosis infections are common with the TNF-α inhibitors 
and latent infections can be reactivated.

• It is advisable to vaccinate patients against common infections.

• Opportunistic fungal viral and bacterial infections are 
common. 

• Biological agents do not effect a cure but contribute to 
achieving a state of remission.

• Withdrawal of biological agents or DMARDs in patients who 
are in remission causes reactivation of the disease.

Table 2. Summary of the non-TNF-α biological DMARDs, their dosage, primary indications and common and serious adverse effects

Immune modulator Dose and interval Indications Adverse effects

Abatacept
(Orencia)

Induction dose: week 0, 2 and 4  500 mg
Thereafter  monthly dose:
< 60 kg: 500 mg
60–100 kg  750 mg
> 100kg : 1000 mg
Intravenous

Rheumatoid arthritis, Juvenile 
idiopathic arthritis

Infusion reactions,
Infections

Rituximab
(Mabthera)

Two IV infusions of 1000 mg two week 
interval 
Repeat 6–9 months
Intravenous

Rheumatoid arthritis, 
Haematological malignancies,
ANCA associated vasculitis,
Non-Hodgkin’s lymphoma,
Chronic lymphocytic lymphoma

Infusion reaction,
Infections,
Reactivation of hepatitis B,
Multifocal leuko-encephalopathy

Tocilizumab
(Actemra)

8 mg every two weeks
Intravenous

Rheumatoid arthritis, 
Systemic juvenile idiopathic arthritis,
Juvenile idiopathic arthritis

Infusion reaction,
Infections,
Dyslipidaemia,
GI perforation

Ustekinumab
(Stelara)

45 mg/100 kg /month (twice) then 45 mg/ 
100 kg every 12 weeks
Intravenous

Psoriatic arthritis,
Plaque psoriasis, 
Crohn’s disease

Infections,
Headache,
Pain – pharynx, larynx,
Myalgia,
Exfoliative dermatitis,
Hypersensitivity,
Malignancies



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Conclusion

The target-specific biological agents are clinically useful 
additions to the DMARDs and improve the chance to achieve 
remission in patients with rheumatoid arthritis. Their crippling 
cost, however, limit their use in resource-poor countries. The risk 
for serious infections in patients on biological DMARDs is of great 
importance and patients require regular monitoring.

Conflict of interest

I declare that I have no financial or personal relationship(s) which 
may have inappropriately influenced me in writing this paper.

References

1. Singh JA, Saag KG, Louis-Bridges Jr S, et al. 2015 American College of 
Rheumatology Guideline for the Treatment of Rheumatoid Arthritis. Arthritis 
Rheumatol. 2016;68:126. 

2. Van Vollenhoven RF. Treatment of rheumatoid arthritis: state of the art. Nat. Rev. 
Rheumatol. 2009;5:531-41.

3. Hazlewood GS, Barnabe C, Tomlinson G, Marshall D, Devoe D, Bombardier 
C. Methotrexate monotherapy and methotrexate combination therapy with 
traditional and biologic disease modifying antirheumatic drugs for rheumatoid 
arthritis: abridged Cochrane systematic review and network meta-analysis. Br 
Med J. 2016;353: i1777. 

4. Brennan FM, Chantry D, Jackson A, Maini R, Feldman M. Inhibitory effect of 
TNF-alpha antibodies to synovial cell interleukin -1 production in rheumatoid 
arthritis. Lancet. 1989;2:244-7.

5. Tarr G, Hogdkinson B, Reuter H. Superheroes in autoimmune warfare: Biologic 
therapies in current South African practice. S Afr Med J. 2014;104(11):787-91. 

6. Scott DL. Biologics-Based Therapy for the Treatment of Rheumatoid Arthritis. Nat 
Rev Clin Phar Ther. 2012;91(1):30-43.

7. Hernández MV, Meineri M, Sanmartí R. Skin Lesions and Treatment with Tumor 
Necrosis Factor Alpha Antagonists. Reumatol Clin. 2013;9(1):53-61.

8. Vasanthi P, Nalini G, Rajasekahr G. Role of tumor necrosis factor-alpha in 
rheumatoid arthritis: a review. APLAR Journal of Rheumatology. 2007;10:270-4.

9. Emery P, Breedveld FC, Hall S, et al. Comparison of methotrexate monotherapy 
with a combination of methotrexate and etanercept in active, early moderate 
to severe rheumatoid arthritis (COMET ): a randomised, double blind, parallel 
treatment trial. Lancet. 2008;372:375-82.

10. Kremer JM, Westhovens R, Leon M, et al. Treatment of rheumatoid arthritis by 
selective inhibition of T‑cell activation with fusion protein CTLA4Ig.  N. Engl. J. 
Med. 2003;349:1907-15.

11. Genovese MC, Becker JC, Schiff M, et al. Abatacept for rheumatoid arthritis 
refractory to tumor necrosis factor alpha inhibition. N. Engl J Med. 
2005;353(11):1114-23.

12. Emery P, Fleischmann R, Filipowicz-Sosnowska A, et al. The efficacy and safety 
of rituximab in patients with active rheumatoid arthritis despite methotrexate 
treatment: results of a phase IIB randomized, double-blind, placebo-controlled, 
dose-ranging trial. Arthritis Rheum. 2006;54:1390-1400.

13. Cohen SB, Emery P, Greenwald MW, et al. Rituximab for rheumatoid arthritis 
refractory to anti-tumor necrosis factor therapy: results of a multicenter, 
randomized, double-blind, placebo-controlled, phase III trial evaluating primary 
efficacy and safety at twenty four weeks. Arthritis Rheum. 2006;5:2793-2806.

14. Clifford DB, Ances B, Costello C, et al. Rituximab associated progressive 
multifocal leukoencephalopathy in rheumatoid arthritis. Arch. Neur. 2011; 
68:1156-64.

15. Scheller J, Garbers C, Rose-John S. Interleukin-6: from basic biology to selective 
blockade of pro-inflammatory activities. Semin Immunol. 2014;26(1):2-12.

16. Gottlieb A, Menter A, Mendelsohn A, et al. Ustekinumab, a human interleukin 
12/23 monoclonal antibody, for psoriatic arthritis: randomised, double-blind, 
placebo-controlled, crossover trial. Lancet. 2009;373:63340.