Chicken Anti-Protein L for the Detection of Small Amounts of Protein L in the Presence of IgG

Passive immunization of mice with IgY anti-H5N1 protects against experimental influenza virus infection and allows development of protective immunity

Influenza virus contributes substantially to the global human and animal disease burden. To protect individuals against disease, strategies are needed to minimize the time an individual is at risk of developing disease symptoms. Passive immunization using avian IgY antibodies can protect individuals against a variety of pathogens, including influenza virus. Yet the effect of IgY administration on generation of protective immunity is largely unknown. To address the effect of passive immunization on the host immune response development, adult or aged, male and female C57BL/6NCrl mice received chicken IgY anti-H5N1, normal IgY or PBS intranasally four hours before, and 20 hours after intranasal infection with H1N1 influenza A virus (PR8). The mice receiving cross-reactive IgY anti-H5N1 were protected from disease and developed influenza virus-specific memory T cells similar to control-treated mice. When re-challenged with PR8 35 days post primary infection IgY anti-H5N1-treated mice were fully protected. Moreover, when challenged with heterologous H3N2 influenza A virus (X-31) or with PR8 three months post infection the mice were protected against severe disease and death, albeit a slight transient weight loss was noted. The results show that passive immunization with IgY anti-H5N1 is safe and protects mice against disease induced by influenza virus without inhibiting development of protective immunity after virus exposure. This indicate that passive immunization can be used as prophylactic therapy in combination with immunization to prevent disease.

IgY antibodies: The promising potential to overcome antibiotic resistance

Antibiotic resistant bacteria are a growing threat to global health security. Whilst the emergence of antimicrobial resistance (AMR) is a natural phenomenon, it is also driven by antibiotic exposure in health care, agriculture, and the environment. Antibiotic pressure and inappropriate use of antibiotics are important factors which drive resistance. Apart from their use to treat bacterial infections in humans, antibiotics also play an important role in animal husbandry. With limited antibiotic options, alternate strategies are required to overcome AMR. Passive immunization through oral, nasal and topical administration of egg yolk-derived IgY antibodies from immunized chickens were recently shown to be effective for treating bacterial infections in animals and humans. Immunization of chickens with specific antigens offers the possibility of creating specific antibodies targeting a wide range of antibiotic-resistant bacteria. In this review, we describe the growing global problem of antimicrobial resistance and highlight the promising potential of the use of egg yolk IgY antibodies for the treatment of bacterial infections, particularly those listed in the World Health Organization priority list.

IgY-technology (egg yolk antibodies) in human medicine: A review of patents and clinical trials

IgY-technology (the production and extraction of specific IgY antibodies from egg yolk) is an innovative method to produce antibodies for therapy and prophylaxis. Advantages of IgY over other antibodies comprise its cost-effective extraction, the minimization of animal harm and distress, and its reduced reactivity with mammalian factors. Many research groups have demonstrated that IgY is active against several pathogens or conditions, a fact that may support the design of novel, safe and effective health products. This review provides a comprehensive analysis of IgY-based biologicals for human medicine, including patent applications and clinical trials during the period 2010-2018, and addresses how IgY-technology can lead to innovation in the production of biologicals for the treatment and prophylaxis of a wide range of infectious and non-communicable diseases.

Use of IgY antibodies and semiconductor nanocrystal detection in cancer biomarker quantitation

Biomarkers play a pivotal role in the early detection and diagnosis of cancer. Accurate quantitation of certain biomarkers is crucial to reach correct treatment decisions. In practice, immunohistochemistry (IHC) remains the most important diagnostic technique to evaluate protein biomarker expression in tissue biopsies. However, IHC has largely been qualitative. Low specificity of the mammalian IgG antibodies used to capture the analytes and instability of fluorescence from the organic dyes used as the detecting agents are among the major factors that have impeded the development of quantitative IHC. Avian IgY antibodies have many attractive biochemical, immunological and production advantages over IgGs and are, therefore, better substitutes in diagnostic applications. Using IgY in immunoassays can potentially eliminate false positives and often results in low background and interference. Quantum dots (QDs) have recently emerged as a novel class of fluorophores, promising for many biomedical imaging applications. Fluorescence from QDs is significantly brighter and more photostable than organic dyes. In addition, QDs offer the capacity of multiplexed detection of several biomarkers simultaneously. Combining the high sensitivity and specificity of IgY antibodies and the high brightness and photostability of QDs in IHC has been demonstrated to improve biomarker detection and quantitation.