When the immune system is fighting pathogens, cytokines signal immune cells such as T-cells and macrophages to travel to the site of infection. In addition, cytokines activate those cells, stimulating them to produce more cytokines. Normally, the body keeps this feedback loop in check. However, in some instances, the reaction becomes uncontrolled, and too many immune cells are activated in a single place. The precise reason for this is not entirely understood but may be caused by an exaggerated response when the immune system encounters a new and highly pathogenic invader. Cytokine storms have potential to do significant damage to body tissues and organs. If a cytokine storm occurs in the lungs, for example, fluids and immune cells such as macrophages may accumulate and eventually block off the airways, potentially resulting in death.

The cytokine storm is the systemic expression of a healthy and vigorous immune system resulting in the release of more than 150 known inflammatory mediators (cytokines, oxygen free radicals, and coagulation factors). Both pro-inflammatory cytokines (such as tumor necrosis factor-alpha, Interleukin-1, and Interleukin-6) and anti-inflammatory cytokines (such as interleukin 10 and interleukin 1 receptor antagonist) are elevated in the serum of patients experiencing a cytokine storm.

Cytokine storms can occur in a number of infectious and non-infectious diseases including graft-versus-host disease (GVHD), acute respiratory distress syndrome (ARDS), sepsis, Ebola, avian influenza, smallpox, and systemic inflammatory response syndrome (SIRS). Cytokine storm may also be induced by certain medications, such as the CD20 antibody rituximab and the CD19 antibody tisagenlecleucel. The experimental drug TGN1412 caused extremely serious symptoms when given to six participants in a Phase I trial.

The first reference to the term "cytokine storm" in the published medical literature appears to be by Ferrara et al. in 1993 in a discussion of graft vs. host disease; a condition in which the role of excessive and self-perpetuating cytokine release had already been under discussion for many years. The term next appeared in a discussion of pancreatitis in 2002, and in 2003 it was first used in reference to a reaction to an infection.

The primary symptoms of a cytokine storm are high fever, swelling, redness, extreme fatigue, and nausea. In some cases the immune reaction will be fatal.

CRS is an adverse effect of some drugs and is a form of systemic inflammatory response syndrome.

The Common Terminology Criteria for Adverse Events classifications for CRS as of version 4.03 issued in 2010 were:

Cytokine release syndrome is an adverse effect of some monoclonal antibody drugs, as well as adoptive T-cell therapies. Severe cases have been called "cytokine storms", a term borrowed from discussions of the pathophysiology of immune disorders and infectious disease.

CRS has been known since the approval of the first monoclonal antibody drug, Muromonab-CD3, which causes CRS, but people working in the field of drug development at biotech and pharmaceutical companies, regulatory agencies, and academia began to more intensely discuss methods to classify it and how to mitigate its risk following the disastrous 2006 Phase I clinical trial of TGN 1412, in which the six subjects experienced severe CRS.

Hypereosiophilia or eosinophilia may be associated with the following autoimmune diseases: systemic lupus erythematosus eosinophilic fasciitis, eosinophilic granulomatosis with polyangiitis, dermatomyositis, severe rheumatoid arthritis, progressive systemic sclerosis, Sjogren syndrome, thromboangiitis obliterans, Behcet syndrome, IgG4-related disease, inflammatory bowel diseases, sarcoidosis, bullous pemphigoid, and dermatitis herpetiformis.

Helminths are common causes of hypereosiophilia and eosinophilia in areas endemic to these parasites. Helminths infections causing increased blood eosinophil counts include: 1) nematodes, (i.e. "Angiostrongylus cantonensis" and Hookworm infections), ascariasis, strongyloidiasis trichinosis, visceral larva migrans, Gnathostomiasis, cysticercosis, and echinococcosis; 2) filarioidea, i.e. tropical pulmonary eosinophilia, loiasis, and onchocerciasis; and 3) flukes, i.e. shistosomiasis, fascioliasis, clonorchiasis, paragonimiasis, and fasciolopsiasis. Other infections associated with increased eosinophil blood counts include: protozoan infections, i.e. "Isospora belli" and "Dientamoeba fragilis") and sarcocystis); fungal infections (i.e. disseminated histoplasmosis, cryptococcosis especially in cases with [[central nervous system]] involvement), and coccidioides); and viral infections, i.e. Human T-lymphotropic virus 1 and HIV.

An increase in eosinophils, i.e., the presence of more than 500 eosinophils/microlitre of blood is called an eosinophilia, and is typically seen in people with a parasitic infestation of the intestines; autoimmune and collagen vascular disease (such as rheumatoid arthritis) and Systemic lupus erythematosus; malignant diseases such as eosinophilic leukemia, clonal hypereosinophilia, and Hodgkin's disease; lymphocyte-variant hypereosinophilia; extensive skin diseases (such as exfoliative dermatitis); Addison's disease and other causes of low corticosteroid production (corticosteroids suppress blood eosinophil levels); reflux esophagitis (in which eosinophils will be found in the squamous epithelium of the esophagus) and eosinophilic esophagitis; and with the use of certain drugs such as penicillin. But, perhaps the most common cause for eosinophilia is an allergic condition such as asthma. In 1989, contaminated L-tryptophan supplements caused a deadly form of eosinophilia known as eosinophilia-myalgia syndrome, which was reminiscent of the Toxic Oil Syndrome in Spain in 1981.

Eosinophils play an important role in asthma as the number of accumulated eosinophils corresponds to the severity of asthmatic reaction. Eosinophilia in mice models are shown to be associated with high interleukin-5 levels. Furthermore, mucosal bronchial biopsies conducted on patients with diseases such as asthma have been found to have higher levels of interleukin-5 leading to higher levels of eosinophils. The infiltration of eosinophils at these high concentrations causes an inflammatory reaction. This ultimately leads to airway remodelling and difficulty of breathing.

Eosinophils can also cause tissue damage in the lungs of asthmatic patients. High concentrations of eosinophil major basic protein and eosinophil-derived neurotoxin that approach cytotoxic levels are observed at degranulation sites in the lungs as well as in the asthmatic sputum.

While the main features of this paraneoplastic disease have been described, the exact mechanism behind its development, progression, and manifestations remain elusive. Overproduction of the myeloma protein and VEGF may underlie some, but are insufficient to explain all, of the multi-organ features of the disease. It is suggested that various other cytokines produced by the clonal plasma cells, perhaps working in concert with each other as well as with VEGF and the myeloma proteins, mediate many of the features of POEMS syndrome. The other cytokines detected in, and suspected of contributing to, POEMS syndrome include interleukin 1β, interleukin 6, and TNFα. Nonetheless, it seems likely that some of these paraneoplastic factors, operating individually, make a major contribution to certain features of the disease. For example, VEGF, given its ability to stimulate blood vessel formation, would seem likely to be the major contributor to the pathologic hyper-vascularization changes seem in many tissues, such as lymph nodes, afflicted by POEMS syndrome.

Some features have been observed in patients with POEMS syndrome but are not yet certain to form part of the syndrome itself. These include a predisposition to forming blood clots, joint pain, cardiomyopathy (systolic dysfunction), fever, low vitamin B12 levels, and diarrhea.

Lymphocyte-variant hypereosinophila, also termed lymphocyte variant eosinophilia, is a rare disorder in which eosinophilia or hypereosinophilia (i.e. a large or extremely large increase in the number of eosinophils in the blood circulation) is caused by aberrant population of lymphocytes. These aberrant lymphocytes function abnormally by stimulating the proliferation and maturation of bone marrow eosinophil-precursor cells termed colony forming unit-Eosinophils or CFU-Eos.

The overly stimulated CFU-Eos cells mature to apparently normal eosinophils, enter the circulation, and may accumulate in, and severely damage, various tissues. The disorder is usually indolent or slowly progressive but may proceed to a leukemic phase and at this phases is sometimes classified as acute eosinophilic leukemia. Hence, lymphocyte-variant hypereosinophilia can be regarded as a precancerous disease.

The order merits therapeutic intervention to avoid or reduce eosinophil-induced tissue injury and to treat its leukemic phase. The latter phase of the disease is aggressive and typically responds relatively poorly to anti-leukemia chemotherapeutic drug regimens.

Treatments used to combat autoimmune diseases and conditions caused by eosinophils include:

- corticosteroids – promote apoptosis. Numbers of eosinophils in blood are rapidly reduced

- monoclonal antibody therapy – e.g., mepolizumab or reslizumab against IL-5, prevents eosinophilopoiesis

- antagonists of leukotriene synthesis or receptors

- imatinib (STI571) – inhibits PDGF-BB in hypereosinophilic leukemia

Monoclonal antibodies such as dupilumab and lebrikizumab target IL-13 and its receptor, which reduces eosinophilic inflammation in pateints with asthma due to lowering the number of adhesion molecules present for eosinophils to bind to, thereby decreasing inflammation. Mepolizumab and benralizumab are other treatment options that target the alpha subunit of the IL-5 receptor, thereby inhibiting its function and reducing the number of developing eosinophils as well as the number of eosinophils leading to inflammation through antibody-dependent cell-mediated cytotoxicity and eosinophilic apoptosis.

Lymphocyte-variant hypereosinophilia usually takes a benign and indolent course. Long term treatment with corticosteroids lowers blood eosinophil levels as well as suppresses and prevents complications of the disease in >80% of cases. However, signs and symptoms of the disease recur in virtually all cases if corticosteroid dosages are tapered in order to reduce the many adverse side effects of corticosteroids. Alternate treatments used to treat corticosteroid resistant disease or for use as corticosteroid-sparing substitutes include interferon-α or its analog, Peginterferon alfa-2a, Mepolizumab (an antibody directed against IL-5), Ciclosporin (an Immunosuppressive drug), imatinib (an inhibitor of tyrosine kinases; numerous tyrosine kinase cell signaling proteins are responsible for the growth and proliferation of eosinophils {see clonal eosinophilia}), methotrexate and Hydroxycarbamide (both are chemotherapy and immunosuppressant drugs), and Alemtuzumab (a antibody that binds to the CD52 antigen on mature lymphocytes thereby marking them for destruction by the body). The few patients who have been treated with these alternate drugs have exhibited good responses in the majority of instances. Reslizumab, a newly developed antibody directed against interleukin 5 that has been successfully used to treat 4 patients with the hypereosinophilic syndrome, may also be of use for lymphocyte-variant eosinophilia. Patients suffering minimal or no disease complications have gone untreated.

In 10% to 25% of patients, mostly 3 to 10 years after initical diagnosis, the indolent course of lymphocyte-variant hypereosinophilia changes. Patients exhibit rapid increases in lymphadenopathy, spleen size, and blood cell numbers, some cells of which take on the appearance of immature and/or malignant cells. Their disease soon thereafter escalates to an angioimmunoblastic T-cell lymphoma, peripheral T cell lymphoma, Anaplastic large-cell lymphoma (which unlike most lymphomas of this type is Anaplastic lymphoma kinase-negative), or Cutaneous T cell lymphoma. The malignantly transformed disease is aggressive and has a poor prognosis. Recommended treatment includes chemotherapy with Fludarabine, Cladribine, or the CHOP combination of drugs followed by bone marrow transplantation.

Cytokine-induced killer cells or CIK cells are a group of immune effector cells featuring a mixed T- and natural killer (NK) cell-like phenotype. They are generated by ex vivo incubation of human peripheral blood mononuclear cells (PBMC) or cord blood mononuclear cells with interferon-gamma (IFN-γ), anti-CD3 antibody, recombinant human interleukin (IL-) 1 and recombinant human interleukin (IL)-2.

Typically, immune cells detect major histocompatibility complex (MHC) presented on infected cell surfaces, triggering cytokine release, causing lysis or apoptosis. However, CIK cells have the ability to recognize infected or even malignant cells in the absence of antibodies and MHC, allowing for a fast and unbiased immune reaction. This is of particular importance as harmful cells that are missing MHC markers cannot be tracked and attacked by other immune cells, such as T-lymphocytes. As a special feature, terminally differentiated CD3+CD56+ CIK cells possess the capacity for both MHC-restricted and MHC-unrestricted anti-tumor cytotoxicity.

These properties, inter alia, rendered CIK cells attractive as a potential therapy for cancer and viral infections.

Cryopyrin-associated periodic syndrome (CAPS) is a group of rare, heterogeneous autoinflammatory disease characterized by interleukin 1β-mediated systemic inflammation and clinical symptoms involving skin, joints, central nervous system, and eyes. It encompasses a spectrum of three clinically overlapping autoinflammatory syndromes including familial cold autoinflammatory syndrome (FCAS, formerly termed familial cold-induced urticaria), the Muckle–Wells syndrome (MWS), and neonatal-onset multisystem inflammatory disease (NOMID, also called chronic infantile neurologic cutaneous and articular syndrome or CINCA) that were originally thought to be distinct entities, but in fact share a single genetic mutation and pathogenic pathway.

There are many causes of eosinophilia that may underlie eosinophilic myocarditis. These causes are classified as primary (i.e. a defect intrinsic to the eosinophil cell line), secondary (induced by an underlying disorder that stimulates the proliferation and activation of eosinophils), or idiopathic (i.e. unknown cause). Non-idiopathic causes of the disorder are sub-classified into various forms of allergic, autoimmune, infectious, or malignant diseases and hypersensitivity reactions to drugs, vaccines, or transplanted hearts. While virtually any cause for the elevation and activation of blood eosinophils must be considered as a potential cause for eosinophilic myocarditis, the follow list gives the principal types of eosinophilia known or thought to underlie the disorder.

Primary conditions that may lead to eosinophilic myocarditis are:

- Clonal hypereosinophilia.

- Chronic eosinophilic leukemia.

- The idiopathic hypereosinophilic syndrome.

Secondary conditions that may lead to eosinophilic myocarditis are:

- Infections agents:

- Parasitic worms: various "Ascaris, Strongyloides, Schistosoma, filaria, Trematoda", and "Nematode" species. Parasitic infestations often cause significant heart valve disease along with myocarditis and the disorder in this setting is sometimes termed Tropical endomyocardial fibrosis. While commonly considered to be due to the cited parasites, this particular form of eosinophilic myocarditis may more often develop in individuals with other disorders, e.g. malnutrition, dietary toxins, and genetic predisposition, in addition to or place of round worm infestation.

- Infections by protozoa: various "Toxoplasma gondii, Trypanosoma cruzi, trichinella spiralis, Entamoeba", and "Echinococcus" species.

- Viruses: While some viral infections (e.g. HIV) have been considered causes of eosinophilic endocarditis, a study of 20 patients concluded that viral myocarditis lacks the characteristic of eosinophil-induced damage in hearts taken during cardiac transplantation.

- Allergic and autoimmune diseases such as severe asthma, rhinitis, or urticarial, chronic sinusitis, aspirin-induced asthma, allergic bronchopulmonary aspergillosis, chronic eosinophilic pneumonia, Kimura's disease, polyarteritis nodosa, eosinophilic granulomatosis with polyangiitis (i.e. Churg-Strauss syndrome), and rejection of transplanted hearts.

- Malignancies and/or premalignant hematologic conditions not due to a primary disorder in eosinophils such as Gleich's syndrome, Lymphocyte-variant hypereosinophilia Hodgkin disease, certain T-cell lymphomas, acute myeloid leukemia, the myelodysplastic syndromes, systemic mastocytosis, chronic myeloid leukemia, polycythemia vera, essential thrombocythemia, myelofibrosis, chronic myelomonocytic leukemia, and T-lymphoblastic leukemia/lymphoma-associated or myelodysplastic–myeloproliferative syndrome-associated eosinophilias; IgG4-related disease and Angiolymphoid hyperplasia with eosinophilia as well as non-hematologic cancers such as solid tumors of the lung, gastrointestinal tract, and genitourinary tract.

- Hypersensitivity reactions to agents include:

- Antibiotics/anti-viral agents: various penicillins (e.g. penicillin, ampicillin), cephalosporins (e.g. cephalosporin), tetracyclins (e.g. tetracycline), sulfonamides (e.g. sulfadiazine, sulfafurazole), sulfonylureas, antituburcular drugs (e.g. isoniazid, 4-aminosalicylic acid), linezolid, amphotericin B, chloramphenicol, streptomycin, dapsone, nitrofurantoin, metronidazole, nevirapine, efavirenz, abacavir, nevirapine.

- Anticonvulsants/Antipsychotics/antidepressants: phenindione, phenytoin, phenobarbital, lamotrigine, lamotrigine, clozapine, valproic acid, carbamazepine, desipramine, fluoxetine, amitriptyline, olanzapine.

- Anti-inflammatory agents: ibuprofen, indomethacin, phenylbutazone, oxyphenbutazone, acetazolamide, piroxicam, diclofenac.

- Diuretics: hydrochlorothiazide, spironolactone, chlortalidone.

- ACE inhibitors: captopril, enalapril.

- Other drugs: digoxin, ranitidine, lenalidomide, methyldopa, interleukin 2, dobutamine, acetazolamide.

- Contaminants: Unidentified contaminants inrapeseed oil cause the toxic oil syndrome and in commercial batches of the amino acid, L-tryptophan, cause the eosinophilia–myalgia syndrome.

- Vaccinations: Tetanus toxoid, smallpox, and diphtheria/pertussis/tetanus vaccinations.

In some cancers, such as melanoma and colorectal cancer, lymphocytes can migrate into and attack the tumor. This can sometimes lead to regression of the primary tumor.

The international registry on CIK cells (IRCC) was founded in 2011 as an independent organization, dedicated to collect data about clinical trials utilizing CIK cells and subsequent analysis to determine the latest state of clinical CIK cell research. A particular focus is thereby the evaluation of CIK cell efficacy in clinical trials and side effects.

Natural killer T (NKT) cells are a heterogeneous group of T cells that share properties of both T cells and natural killer cells. Many of these cells recognize the non-polymorphic CD1d molecule, an antigen-presenting molecule that binds self and foreign lipids and glycolipids. They constitute only approximately 0.1% of all blood T cells. Natural killer T cells should not be confused with natural killer cells.

The DRESS syndrome is a severe immunological drug reaction. It differs from other drug reactions in that it: a) is caused by a particular set of drugs; b) typically occurs after a delay of 2 to 8 weeks following intake of an offending drug; c) presents with a specific set of signs and symptoms (i.e. modest or extreme elevations in blood eosinophil and atypical lymphocyte counts; acute onset of a skin rash; lymphadenopathy; fever; neuralgia; and involvement of at least one internal organ such as the liver, lung, or heart; d) develops in individuals with particular genetic predispositions; and e) involves reactivation of latent viruses, most commonly human herpesvirus 6 or more rarely human herpes virus 5 (i.e. human cytomegalovirus), human herpesvirus 7, and human herpesvirus 4 (i.e. Epstein–Barr virus). These virus usually become dormant after infecting humans but under special circumstances, such as drug intake, are reactivated and may contribute to serious diseases such as the DRESS syndrome.

The prognosis is guarded with an overall mortality of 50%. Poor prognostic factors included HLH associated with malignancy, with half the patients dying by 1.4 months compared to 22.8 months for non-tumour associated HLH patients.

Secondary HLH in some individuals may be self-limited because patients are able to fully recover after having received only supportive medical treatment (i.e., IV immunoglobulin only). However, long-term remission without the use of cytotoxic and immune-suppressive therapies is unlikely in the majority of adults with HLH and in those with involvement of the central nervous system (brain and/or spinal cord).

A lymphocyte is one of the subtypes of white blood cell in a vertebrate's immune system. Lymphocytes include natural killer cells (Phagocytes) (which function in cell-mediated, cytotoxic innate immunity), T cells (for cell-mediated, cytotoxic adaptive immunity), and B cells (for humoral, antibody-driven adaptive immunity). They are the main type of cell found in lymph, which prompted the name "lymphocyte".

Cryopyrin-associated periodic syndromes are associated with a gain-of-function missense mutation in exon 3 of "NLRP3", the gene encoding cryopyrin, a major component of the interleukin 1 inflammasome. Intracellular formation of the interleukin 1 inflammasome leads to the activation of the potent pro-inflammatory cytokines interleukin 1β and interleukin-18 through a cascade involving caspase 1. The IL-1 inflammasome may also be released from activated macrophages, amplifying the cytokine production cascade. The mutation in "NLRP3" leads to aberrant formation of this inflammasome and subsequent unregulated production of interleukin 1β.

Up to 170 heterogenous mutations in "NLRP3" have been identified . Some reports suggest rare mutations are more frequently associated with a severe phenotype, and some mutations are associated with distinct phenotypes, probably reflecting the differential impact of the mutation on the activity of the inflammasome in the context of individual genetic background. Inheritance of these disorders is autosomal dominant with variable penetrance.

The causes of SIRS are broadly classified as infectious or noninfectious. Causes of SIRS include:

- trauma

- burns

- pancreatitis

- ischemia

- hemorrhage

Other causes include:

- Complications of surgery

- Adrenal insufficiency

- Pulmonary embolism

- Complicated aortic aneurysm

- Cardiac tamponade

- Anaphylaxis

- Drug overdose

Without HSCT the condition is inevitably fatal and even HSCT is no guarantee, with a significant portion of patients dying from the disease progression. Factors indicative of a poor prognosis include: thrombocytopenia, late onset of the disease (age ≥ 8 years) and T cell involvement.

It arises from the cells that constitute the immune system, most often the T-cells and NK cells in Asians/South Americans and the B-cells in the other racial groups. Various cytokine anomalies have been reported in people with CAEBV, examples include:

- IL-1β ↑ (elevated)

- IL-4 ↑

- IL-6 ↑

- IL-10 ↑

- IL-12 ↑

- IL-13 ↑

- IL-15 ↑

- TNF ↑

- IFN-γ ↑

There is also evidence supporting a role for TGF-β in the disease. Those that develop the haemophagocytic syndrome often exhibit an abnormally high amount of IL-1β and IFN-γ.