8^th European Immunology Conference June 29-July 01, 2017 Madrid, Spain

Autoimmune diseases can affect almost any part of the body, including the heart, brain, nerves, muscles, skin, eyes, joints, lungs, kidneys, glands, the digestive tract, and blood vessels.

The classic sign of an autoimmune disease is inflammation, which can cause redness, heat, pain, and swelling. How an autoimmune disease affects you depends on what part of the body is targeted. If the disease affects the joints, as in rheumatoid arthritis, you might have joint pain, stiffness, and loss of function. If it affects the thyroid, as in Graves’ disease and thyroiditis, it might cause tiredness, weight gain, and muscle aches. If it attacks the skin, as it does in scleroderma/systemic sclerosis, vitiligo, and systemic lupus erythematosus (SLE), it can cause rashes, blisters, and color changes.Many autoimmune diseases don’t restrict themselves to one part of the body. For example, SLE can affect the skin, joints, kidneys, heart, nerves, blood vessels, and more. Type 1 diabetes can affect your glands, eyes, kidneys, muscles, and more.

Immunotherapy, also called biologic therapy, is a type of cancer treatment designed to boost the body's natural defenses to fight the cancer. It uses materials either made by the body or in a laboratory to improve, target, or restore immune system function.Immunotherapy is treatment that uses certain parts of a person’s immune system to fight diseases such as cancer. This can be done in a couple of ways:1)Stimulating your own immune system to work harder or smarter to attack cancer cells2)Giving you immune system components, such as man-made immune system proteinsSome types of immunotherapy are also sometimes called biologic therapy or biotherapy.

In the last few decades immunotherapy has become an important part of treating some types of cancer. Newer types of immune treatments are now being studied, and they’ll impact how we treat cancer in the future. Immunotherapy includes treatments that work in different ways. Some boost the body’s immune system in a very general way. Others help train the immune system to attack cancer cells specifically. Immunotherapy works better for some types of cancer than for others. It’s used by itself for some of these cancers, but for others it seems to work better when used with other types of treatment.

Infectious diseases are caused by pathogenic microorganisms, such as bacteria, viruses, parasites or fungi; the diseases can be spread, directly or indirectly, from one person to another. Zoonotic diseases are infectious diseases of animals that can cause disease when transmitted to humans. Some infectious diseases can be passed from person to person. Some are transmitted by bites from insects or animals. And others are acquired by ingesting contaminated food or water or being exposed to organisms in the environment.Signs and symptoms vary depending on the organism causing the infection, but often include fever and fatigue. Mild complaints may respond to rest and home remedies, while some life-threatening infections may require hospitalization.

Many infectious diseases, such as measles and chickenpox, can be prevented by vaccines. Frequent and thorough hand-washing also helps protect you from infectious diseases

There are four main kinds of germs:

• Bacteria - one-celled germs that multiply quickly and may release chemicals which can make you sick
• Viruses - capsules that contain genetic material, and use your own cells to multiply
• Fungi - primitive plants, like mushrooms or mildew
• Protozoa - one-celled animals that use other living things for food and a place to live

Immunodeficiency is a state in which the immune system's ability to fight infectious disease is compromised or entirely absent. Immunodeficiency disorders prevent your body from adequately fighting infections and diseases. An immunodeficiency disorder also makes it easier for you to catch viruses and bacterial infections in the first place. Immunodeficiency disorders are often categorized as either congenital or acquired. A congenital, or primary, disorder is one you were born with. Acquired, or secondary, disorders are disorders you get later in life. Acquired disorders are more common than congenital disorders. Immune system includes the following organs: spleen, tonsils, bone marrow, lymph nodes. These organs make and release lymphocytes. Lymphocytes are white blood cells classified as B cells and T cells. B and T cells fight invaders called antigens. B cells release antibodies specific to the disease your body detects. T cells kill off cells that are under attack by disease. An immunodeficiency disorder disrupts your body’s ability to defend itself against these antigens. Types of immunodeficiency disorder are Primary immunodeficiency disorders & Secondary  immunodeficiency  disorders.

Primary immunodeficiency disorders are immune disorders you are born with. Primary disorders include:

X-linked agammaglobulinemia (XLA)

·         Common variable immunodeficiency (CVID)

·         Severe combined immunodeficiency (SCID)

Secondary disorders happen when an outside source, such as a toxic chemical or infection, attacks your body. Severe burns and radiation also can cause secondary disorders.

Secondary disorders include: AIDS, cancers of the immune system  such as leukemia, immune-complex diseases such as viral hepatitis, multiple myeloma.

Reproductive immunology refers to a field of medicine that studies interactions (or the absence of them) between the immune system and components related to the reproductive system, such as maternal immune tolerance towards the fetus, or immunological interactions across the blood-testis barrier. The immune system refers to all parts of the body that work to defend it against harmful enemies. In people with immunological fertility problems their body identifies part of reproductive function as an enemy and sends Natural Killer (NK) cells to attack. A healthy immune response would only identify an enemy correctly and attack only foreign invaders such as a virus, parasite, bacteria, ect.

The concept of reproductive immunology is not widely accepted by all physicians. Those patients who have had repeated miscarriages and multiple failed IVF's find themselves exploring it's possibilities as the reason. With an increased amount of success among treating any potential immunological factors, the idea of reproductive immunology can no longer be overlooked.The failure to conceive is often due to immunologic problems that can lead to very early rejection of the embryo, often before the pregnancy can be detected by even the most sensitive tests. Women can often produce perfectly healthy embryos that are lost through repeated "mini miscarriages." This most commonly occurs in women who have conditions such as endometriosis, an under-active thyroid gland or in cases of so called "unexplained infertility." It has been estimated that an immune factor may be involved in up to 20% of couples with otherwise unexplained infertility. These are all conditions where abnormalities of the woman’s immune system may play an important role.

Microbial Immunology expects studies examining responses to any microbial agent, including viruses, bacteria and parasites. The Microbiology, Microbial Pathogenesis and Immunology concentrates on the study of host-pathogen interactions at the molecular and cellular levels

Most parasites, by the nature of their continuous contact with the immune system, generate a prolific immune response. Unfortunately, much of this response is not protective, and some is harmful. Protective immunity in some infections is due to a combination of humoral and cellular immunity; in this circumstance parasites are coated with antibody which makes them susceptible to direct cytotoxicity by macrophages, eosinophils, and neutrophils. Antibody alone is protective against some other infections. Nonspecific and genetic factors are clearly important but are still undefined participants in the host response. The immune response may be pathogenic by inducing hypersensitivity, immunologically mediated fibrosis, or circulating immune complexes. Additionally, Parasites have evolved unique ways of protecting themselves from the immune system, including altering their antigenic coat and inducing immunosuppression. Attempts to isolate "host-protective" antigens in parasitic infections may lead to effective vaccine development

Autoimmunity is the system of  immune responses of an organism against its own cells and tissues. Any disease that results from such an aberrant immune response is termed an autoimmune disease.

Autoimmunity is present to some extent in everyone and is usually harmless. However, autoimmunity can cause a broad range of human illnesses, known collectively as autoimmune diseases. Autoimmune diseases occur when there is progression from benign autoimmunity to pathogenic autoimmunity. This progression is determined by genetic influences as well as environmental triggers. Autoimmunity is evidenced by the presence of autoantibodies (antibodies directed against the person who produced them) and T cells that are reactive with host antigens.

Current treatments for allergic and autoimmune disease treat disease symptoms or depend on non-specific immune suppression. Treatment would be improved greatly by targeting the fundamental cause of the disease, that is the loss of tolerance to an otherwise innocuous antigen in allergy or self-antigen in autoimmune disease (AID). Much has been learned about the mechanisms of peripheral tolerance in recent years. We now appreciate that antigen presenting cells (APC) may be either immunogenic or tolerogenic, depending on their location, environmental cues and activation state

Diagnostic Immunology. Immunoassays are laboratory techniques based on the detection of antibody production in response to foreign antigens. Antibodies, part of the humoral immune response, are involved in pathogen detection and neutralization.

Diagnostic immunology has considerably advanced due to the development of automated methods.New technology takes into account saving samples, reagents, and reducing cost.The future of diagnostic immunology faces challenges in the vaccination field for protection against HIV and as anti-cancer therapy. Modern immunology relies heavily on the use of antibodies as highly specific laboratory reagents. The diagnosis of infectious diseases, the successful outcome of transfusions and transplantations, and the availability of biochemical and hematologic assays with extraordinary specificity and sensitivity capabilities all attest to the value of antibody detection.Immunologic methods are used in the treatment and prevention of infectious diseases and in the large number of immune-mediated diseases. Advances in diagnostic immunology are largely driven by instrumentation, automation, and the implementation of less complex and more standardized procedures.

Examples of such processes are as follows:

• miniaturization (use of microtiter plates to save samples and reagents),
• amplified  immunoassays (chemiluminesent ELISA),
• flow cytometry with monoclonal antibodies,
• Immunoglobulins,
• Molecular methods (polymerase chain reactions).

These methods have facilitated the performance of tests and have greatly expanded the information that can be developed by a clinical laboratory. The tests are now used for clinical diagnosis and the monitoring of therapies and patient responses. Immunology is a relatively young science and there is still so much to discover. Immunologists work in many different disease areas today that include allergy, autoimmunity, immunodeficiency, transplantation, and cancer.

Haematopoiesis is the synthesis and development of Blood cells. Occurs during embryonic development and throughout adulthood to produce and replenish the blood system. Cellular blood components are derived from haematopoietic stem cells that reside mainly in the bone marrow, a major site of adult haematopoiesis. The blood system contains more than 10 different blood cell types with various functions: Leukocytes represent many specialized cell types involved in innate and acquired immunity. Erythrocytes provide O2 and CO2 transport, whereas megakaryocytes generate platelets for blood clotting and wound healing.

Immune System Development:

Our immune system defends people against germs and microorganisms. The immune system consists of lymphoid organs that can be divided into the primary and secondary immune systems as well as the myeloid and lymphoid cells, these arise via haematopoiesis. The primary lymphoid organs are the bone marrow and thymus. These are the sites at which haematopoiesis occurs and immature lymphocytes grow, develop, and differentiate. The secondary, or peripheral, lymphoid organs primarily consist of the spleen and lymph nodes and play roles in antigen presentation and adaptive immune response initiation.

Immunoinformatics is a branch of bioinformatics dealing with in silico analysis and modelling of immunological data and problems Immunoinformatics includes the study and design of algorithms for mapping potential B- and T-cell epitopes, which lessens the time and cost required for laboratory analysis of pathogen gene products. Using this information, an immunologist can explore the potential binding sites, which, in turn, leads to the development of new vaccines. This methodology is termed ‘reverse vaccinology’ and it analyses the pathogen genome to identify potential antigenic proteins.⁵ This is advantageous because conventional methods need to cultivate pathogen and then extract its antigenic proteins. Although pathogens grow fast, extraction of their proteins and then testing of those proteins on a large scale is expensive and time consuming. Immunoinformatics is capable of identifying virulence genes and surface-associated proteins.