Immunobiologicals are drugs produced through the biosynthesis of living cells. They are large unstable molecules with thousands of atoms and undergo changes with minimal variations in storage and conservation. They are preferably administered by injection or inhalation due to the risk of inactivation by digestive enzymes. They comprise a heterogeneous class of products developed by genetic engineering, which is associated with a high cost for the development of the technology, production, distribution, and storage.1

With the advancement of the knowledge of the physiopathogenesis of inflammatory diseases, the advent of target-specific therapies has produced a revolution in the treatment of immune-mediated diseases and cancer.1

The concept of biological medications is an old one, for instance, with the development of the serum against rabies in 1885 by Pasteur; of insulin from animal pancreas for diabetes in 1922 by Banting and Best; the extraction of growth hormone from cadavers in 1958 by Raben. With the advent of knowledge about the genome in 2000, the possibility of manipulating genes and producing specific proteins became a reality. The production of modified antibodies aimed at specific elements from the fusion of two cells (immunized mouse lymphocytes and tumor cells) in 1975 by Kohler and Milstein was the milestone in the development of monoclonal antibodies. It allowed the development of the immortalized hybridoma, a “mother cell” of a lineage that can be maintained and expanded.1

Groups of known protein synthesis genes can be isolated, recombined as a new gene, and transferred to a host cell that starts producing a new protein. These host cells are called an expression system, and one example is the most simple E. coli, or CHO (Chinese hamster ovary) cells of genetically modified mammals which are more complex. These cells are stored at low temperatures in an immortalized gene bank, and aliquots are removed for cultivation in industrial reactors with nutrients for cell growth and protein production. Subsequently, the product is recovered, separated, and purified.

They are macromolecules and can be immunogenic, with variable or unpredictable consequences, such as hypersensitivity reactions to the product, decreased efficacy due to anti-drug antibody formation, loss of immune tolerance in lupus-like syndromes.

In Brazil, several immunobiologicals are registered and recognized by the Brazilian Health Regulatory Agency (ANVISA/MoH): vaccines, hyperimmune serums, blood products, biomedicines, monoclonal antibodies, drugs containing live, attenuated, or dead microorganisms, probiotics, and allergens.

Antibodies are large heterodimeric protein molecules (molecular weight ∼150 kDa) consisting of two identical light chains and two identical heavy ones, each comprising different domains. They are joined by disulfide bonds, forming a Y-shaped structure. There are five classes of antibodies based on their heavy chain sequences: IgM, IgD, IgG, IgE, and IgA, and each class has different subtypes (IgG1, IgG2, IgG3, and IgG4). They are naturally polyclonal, i.e., produced by several clones of B lymphocytes. They specifically bind to foreign proteins, against which they were produced after sensitization. Monoclonal antibodies, in turn, are produced by a single clone of cells, in the case of hematological or autoimmune diseases, for instance, or in the case of genetically manipulated hybridomas to produce biological drugs with specific therapeutic targets. Monoclonal antibodies produced for clinical purposes are IgG because of their prolonged circulation, longer half-life, and relatively easy production.1

The first generation of monoclonal antibodies was mouse-derived, had lower receptor affinity, short half-lives, and was unable to deactivate the human complement system, causing intense hypersensitivity reactions.2

The second generation antibodies can be chimeric (contain cDNA from the murine Fab domain coupled to human Fc, which increases plasma half-life fivefold), humanized (replaces Fab and Fc by human proteins, with mouse antigen-binding sites), or human (consisting of recombinant elements of human antibodies).2

Monoclonal antibodies can have several functions, such as labeling or destroying tumor cells, inactivating enzymes, stimulating or inhibiting receptors, turning physiological functions on or off. They are useful in oncological and autoimmune treatments, transplant rejection, as diagnostic markers, and for scientific investigation.2

As for the nomenclature, the suffix generally expresses the nature of the product (mab: monoclonal antibody; ept: fusion protein). The middle syllable denotes the antibody source, one or two letters before the suffix (U: human, O: mouse, E: hamster; I: primate; A: rat). For example, ZU: humanized; XI: chimeric. The prefix initially denoted the disease target to be treated, but with the increasing number of new biologicals, this rule is no longer used. For example: bac (bacterial), lim (immunomodulator), vir (viral), ci (cardiovascular), mel (melanoma), pr(o) (prostate), gov (ovary), col (colon), mar (breast), got (testicles), tum (other tumors).2

Tumor necrosis factor is a cytokine that acts on the activation of macrophages, phagosomes, differentiation of monocytes into macrophages, recruitment of polymorphonuclear cells, and granuloma formation/maintenance. It is secreted by keratinocytes and activates dendritic cells, triggering a Th1 response, which results in the production of other pro-inflammatory cytokines. It also stimulates the production of Th17 cytokines, such as IL-17 and IL-23. Thus, the inhibition of this pathway through medications has shown good responses in dermatological diseases such as plaque psoriasis (PSO) and hidradenitis suppurativa (HS), in addition to several other diseases. They modified the history of psoriasis treatment with a 75% improvement in the Psoriasis Area Severity Index (PASI) by week 16 of treatment, whereas in the prebiological era, the mean PASI was 50.3

Historically, it was conceived as a cachexin-inhibiting molecule for the treatment of shock and sepsis, situations in which this cytokine was high, but the studies had to be interrupted due to the increase in mortality. Some contraindications are common to TNF-α inhibitors, such as multiple sclerosis and other demyelinating diseases, optic neuritis, heart failure functional class 3 or 4, active infections, untreated latent tuberculosis, previous lymphoma or current neoplasia, congenital or acquired immunodeficiency, and hypersensitivity to the formula components.3

Therefore, an extensive anamnesis covering such situations is recommended, in addition to an overall laboratory screening, PPD test (or specific test, if possible), serology for hepatitis B and C, syphilis and HIV, chest X-ray, and targeted tests, if there is a suspicion in the anamnesis. It is also important to pay attention to the vaccination record updating since vaccines with live agents cannot be used during biological therapy.3

TNF plays an important role in fighting infections, whether viral, fungal, or bacterial, being responsible for the stability of tuberculosis caseous granuloma, as well as for the immune response restraint, which is why it is so necessary to rule out the possibility of active disease or latent infection. The same is true for patients with active surface antigen for virus B (HbsAg) when the possibility of reactivation also needs to be discussed.4

The risk of demyelination associated with the use of anti-TNF was raised by a drug, no longer available, called Lenercept, which would have been indicated for multiple sclerosis (MS), but led to its exacerbation, and Efalizumab, a medication used for psoriasis that was withdrawn from the market later due to cases of progressive leukoencephalopathy. Seventeen cases of etanercept-induced MS and two cases induced by infliximab were also reported. In the case of demyelinating diseases, it is postulated that there is an activation of the polyomavirus by the TNF inhibitor, triggering the disease.4

Neoplasm cases should be discussed directly with the assistant team, aiming to make the best decision on when to introduce the immunobiological; recent studies have shown this therapy can be considered in neoplasia cases under remission for at least five years.

TNF-alpha inhibition may be associated with exacerbation of heart failure (HF), according to randomized clinical trials of TNF-alpha inhibitors as a potential therapy for improving cardiac function in HF, whose post-marketing surveillance data collected by the FDA showed exactly the opposite: increased mortality with deterioration of cardiac function in 2001, worsening CHF, with 38 patients developing HF and nine with worsening of previous HF.5

The main adverse effects of TNF-alpha inhibitor drugs are cutaneous infusion reactions (local pruritus, pain, erythema and edema) with the subcutaneous administration of the drug and systemic reactions when the route is intravenous, with acute allergic reactions, anaphylaxis, fever or chronic reactions; cytopenias; infections, most commonly of the upper airways; autoimmunity induction; paradoxical psoriasis, among others.5

Listed below are the drugs approved in Brazil, with proven action in dermatoses, which will be discussed.

IL-12 and IL-23 are heterodimeric cytokines secreted by activated antigen-presenting cells, such as macrophages and dendritic cells. IL-12 stimulates natural killer (NK) cells and conducts the differentiation of CD4+ T-cells into the T Helper 1 (Th1) cell phenotype, and stimulates the production of interferon-gamma (IFNγ). IL-23 induces the T17 helper cell (Th17) pathway and promotes the secretion of IL-17A, IL-21, and IL-22. The levels of IL-12 and IL-23 are elevated in the skin and blood of patients with psoriasis, and serum IL12/23p40 differentiates between patients with psoriatic arthritis and healthy individuals, implicating IL-12 and IL-23 in the pathophysiology of psoriatic inflammatory diseases.11

IL-23 responsive T cells were found in enthesis in a mouse model of inflammatory arthritis, where IL-23 conducts the inflammation of the enthesis. Additionally, there is pre-clinical evidence implicating IL-23 and descending pathways in bone erosion and bone destruction through the increase in the receptor activator of nuclear factor-kappa B ligand (RANKL), which activates osteoclasts. 12

Ustekinumab is a fully human IgG1kappa monoclonal antibody that specifically binds to the p40 shared protein subunit of the human cytokines interleukin 12 (IL-12) and IL-23. Ustekinumab inhibits human IL-12 and IL-23 bioactivity by preventing p40 from binding to the IL-12Rbeta1 protein receptor expressed on the surface of cells from the immunological system.11,12

Approved in Brazil in 2012, the drug has a good safety profile, whose main adverse effects are upper airway infections, local reactions, diarrhea, nausea, and pruritus. Its contraindication is hypersensitivity to the drug components, and it seems to have no action on axial psoriatic arthritis; however, it has a good response in dactylitis and peripheral arthritis. The dose should be adjusted to 90 mg in individuals weighing more than 100 kg.13

The drug showed a sustained response in a 5-year follow-up study since the first pivotal study (PHOENIX 1 and 2) and resulted in PASI 75 in approximately 77% of patients, and PASI 90 in 50%, at week 12. The pivotal studies do not contemplate the metric of PASI 100.

Nevertheless, real-life studies show that the criteria used in the pivotal studies are far from the reality of patients who actually use the drug and that the rate of side effects is slightly higher in the real-life population.14

The drug has shown a good safety profile when compared to methotrexate and other biological drugs, not increasing the risk of MACE, malignancies, or sudden death. There are some case reports in the literature demonstrating the drug is safe to be used in concomitant chronic infections, such as HIV and hepatitis, without reactivation of viral repplication.11–13

As a product of the stimulation of dendritic and antigen-presenting cells by pro-inflammatory cytokines, what is currently generically known as the “type 3 response” is triggered, the Th17 response, with the production of IL-23, which is later transformed into IL-17 and its subunits, with A and F subunits being the most frequently involved in the physiopathogenesis of psoriasis.

This cytokine plays a role in the production of other microbial cytokines and peptides, with the recruitment of neutrophils and polymorphonuclear cells, stimulating the production of IL-1-β and TNF-α through the recruitment of these cells, in addition to contributing to the Th2 response against extracellular organisms. The IL-17 family includes cytokines IL-17A, IL-17B, IL-17C, IL-17D, IL-17E (also referred to as IL-25), and IL-17F.15

In addition to the recruitment of neutrophils, it has an important mucocutaneous presence, which may be related to an increase in oral and genital candidiasis, mostly in mild or moderate cases. It is important to pay attention to this in patients with inflammatory bowel disease (IBD – Crohn's disease and ulcerative colitis) since there are reports of worsening of these diseases during the treatment. However, there are no data to support the conclusion that these drugs induce IBD.16,17

IL-23 is responsible for inflammation, immune activation, and hyperproliferation of the stratum corneum. It is a heterodimer consisting of two subunits: p40, which is common to IL-12 in the Th1 pathway, and p19, which is specific only for IL-23. Messenger RNA levels of both the p19 and p40 subunits for IL-12/IL-23 are increased in psoriasis plaques and decrease during the treatment.

The expression of retinoic acid-related orphan receptors (RORs) activates the production of IL-23 by APCs (antigen-presenting cells) and myeloid dendritic cells, which will act on the entire Th17 and Th22 axis and can transform into effector response cells resident in the affected plaque, even when there is clinical resolution.25

Interleukins 4 (IL-4) and 13 (IL-3) are, together with IL-5, the main effectors of the Th2 immune response. They are produced by cells of innate and adaptive immunity, have antiparasitic action, and are involved in several processes that can culminate in allergic diseases, such as a) Recruitment and activation of Th2 cells, eosinophils, and mast cells; b) B lymphocyte class switch for IgE production; c) Mechanisms involved in pruritus (such as IL-31 production and sensory neuron signaling); in addition to d) Tissue remodeling, fibrosis, and induction of defects in the cutaneous and mucosal barrier. Among the diseases triggered by activation of Th2 immunity are atopic dermatitis (AD), allergic asthma, nasal polyposis, and eosinophilic esophagitis.32,33

A part of the common functions of IL-4 and IL-13 is due to the presence of the IL-4 receptor alpha subunit (IL4Rα), which is shared by the type 2 receptor complex (of IL-4 and IL-13), present in epithelial cells, smooth muscle cells, fibroblasts, monocytes, and activated B cells.33

Dupilumab (Dupixent®) is a fully human IgG4 monoclonal antibody that inhibits IL-4 and IL-13 signaling by binding to the IL4Rα subunit of type 1 and type 2 receptors (common to both cytokines) (Table 2).

It is the first FDA-approved immunobiological for severe atopic dermatitis in adults (2017), followed by its approval for adolescents aged 12 to 17 (2019) and children aged six years and older (2020). Its approval in Brazil follows the same indications. There was considerable improvement in pruritus in all studies, comparable to placebo. At week 16, peak pruritus was significantly reduced by about 1.1–3.2 points from the initial score, also improving quality of sleep in the Dermatology Life Quality Index (DLQI), in addition to significantly reducing anxiety and depression symptoms.33,34

The pivotal SOLO 1 and 2 studies, in patients with moderate AD without improvement with topical measures (including topical corticosteroids and calcineurin inhibitors), achieved EASI 75 (75% improvement from the initial EASI – Eczema Activity Severity Index) and 48% after 16 weeks of use. This percentage increased to 62% when the use of medium-potency topical corticosteroids was associated (CHRONOS study), an effect maintained for 52 weeks and also seen in more severe patients with cyclosporine indication (CAFÉ study). There was considerable improvement in pruritus in all studies, comparable to placebo.34

The common side effects in all studied populations were injection site reaction (the administration is subcutaneous), headache, and conjunctivitis. Also included in this group are allergic, viral, bacterial conjunctivitis, and atopic keratoconjunctivitis. It is important to emphasize that conjunctivitis was not a more frequently observed adverse effect when compared to placebo in dupilumab studies in other Th2-mediated diseases, such as asthma and chronic rhinosinusitis. The etiology of this adverse effect remains uncertain. There was a decrease in skin infections (with the exception of herpes simplex) and AD flare episodes in the dupilumab groups.35

Omalizumab is a humanized anti-IgE monoclonal antibody, which binds to the C3 domain of the IgE heavy chain and prevents binding to the mast cell high-affinity IgE receptor (FcεRI). The medication binds to free IgE, promoting a decrease in the expression of IgE receptors on the cell surface, preventing mast cell degranulation. It was approved in 2014, with an indication for the treatment of chronic spontaneous urticaria for individuals aged 12 years and older.36

The pivotal ASTERIA I and II and GLACIAL studies showed control of urticaria (urticaria activity in 7 days equal to 0 and ≤ 6) in at least 85% of patients compared to placebo (use of a standard dose of antihistamines up to 4× the package insert dose) at week 12, an effect maintained until the end of the study (week 24). Regarding pruritus, the main symptom of urticaria, there was a 71% reduction in the evaluated scores. Real-life experiences in a Brazilian sample achieved complete response (no wheals and no pruritus) in 84% of the patients.36,37

To assess the individual response, it is recommended to maintain the use of omalizumab for six months, as there are fast and slow responders. A progressive increase in treatment response was observed in up to 24 weeks. The treatment should be maintained until complete control of wheals and pruritus (UAS7 = 0).38

The most frequent adverse effects correspond to headache and upper airway infection with the medication use, and tests prior to the treatment are not necessary. There was no increase in infestations or parasitosis.

On 10/29/2019, ANVISA approved its indication for use in moderate to severe pemphigus vulgaris (PV). Rituximab is a humanized chimeric monoclonal antibody directed against the CD20 antigen on B lymphocytes. It works by depleting circulating B lymphocytes for six to 12 months. The indications in the package insert in Brazil include chronic lymphoid leukemia, non-Hodgkin lymphoma, rheumatoid arthritis, and granulomatosis with polyangiitis. In dermatological diseases, therefore, its use is off-label.

The therapeutic effectiveness of this drug has already been evaluated in a series of cases, randomized clinical trials, and meta-analyses. Its administration is through the intravenous route and there are two dosage possibilities: as used in rheumatoid arthritis, that is, 1000 mg in two doses (0 and 15 days), in addition to 500 mg maintenance doses (months 12 and 18) or as used in lymphoma, at a dose of 375 mg/m2/week for four weeks, usually associated with the use of systemic corticosteroids.39

In the RITUX 3 study, in which rituximab plus a short course of prednisone was compared to the use of prednisone alone as first-line treatment, it was possible to demonstrate a higher rate of complete remission off therapy at 24 months (89%×34%), in addition to a steroid-sparing effect with a favorable safety profile in the group treated with rituximab. There is no consensus on the optimal dose of rituximab; a retrospective cohort study found a greater chance of complete remission in patients who submitted to the regimen used in lymphoma cases, but more studies are necessary.40

Moreover, there are studies in nodal lymphomas that compare the intravenous use of rituximab to its subcutaneous use, in which the subcutaneous administration has the same efficacy as the intravenous one, with a higher rate of patient satisfaction; its use in PV is also off-label. In general, rituximab is used together with systemic corticosteroids.41

Other autoimmune diseases can also be treated off-label with rituximab. A meta-analysis highlights bullous pemphigoid, cryoglobulinemia, and IgG4-related diseases as autoimmune diseases showing promising results to the drug use. (Kaegi 2019) In addition to autoimmune diseases, rituximab can be used in cutaneous B-cell lymphomas. There are no randomized studies published yet, but the guidelines of the European Organization for Research and Treatment of Cancer (EORTC), the International Society for Cutaneous Lymphomas, and the National Comprehensive Cancer Network indicate rituximab alone as an option for generalized cutaneous forms of primary centrofollicular and marginal zone lymphoma of the skin.39

Rituximab is contraindicated in patients with hypersensitivity to the active substance or the murine proteins, patients with active, severe infections, severely immunocompromised patients, patients with severe heart failure (class IV), or severe uncontrolled heart disease. This medication should not be used in pregnant and lactating women. The adverse effects include hypersensitivity infusion reactions, cardiovascular events (angina, cardiac arrhythmia, or myocardial infarction), in addition to the potential increased risk of infections, including progressive multifocal leukoencephalopathy and hepatitis B reactivation.42

None declared.

Dimitri Luz Felipe da Silva: Approval of the final version of the manuscript; design and planning of the study; drafting and editing of the manuscript; collection, analysis, and interpretation of data; effective participation in research orientation; critical review of the literature; critical review of the manuscript.

Elisa Nunes Secamili: Drafting and editing of the manuscript; collection, analysis, and interpretation of data; critical review of the manuscript.

Mariana Valbon Beleli: Drafting and editing of the manuscript.

Juliana Yumi Massuda: Collection, analysis, and interpretation of data.

Andrea F. E. C. Franca: Drafting and editing of the manuscript; collection, analysis, and interpretation of data; critical review of the literature.

Renata F. Magalhães: Approval of the final version of the manuscript; design and planning of the study; drafting and editing of the manuscript; collection, analysis, and interpretation of data; effective participation in research orientation; critical review of the literature; critical review of the manuscript.

Dimitri Luz Felipe da Silva, Juliana Yumi Massuda Andrea F. E. C. Franca and Renata F. Magalhães declare they have conflicts of interest regarding the following companies: Lilly, Novartis, Abbvie and Janssen.