Vaccines for preventing or treating diabetes, obesity and complications thereof are provided. The vaccines comprise at least one active agent such as attenuated Porphyromonas gingivalis, inactivated Porphyromonas gingivalis, a subunit of Porphyromonas gingivalis, a recombinant or isolated immunogenic polypeptide or peptide from Porphyromonas gingivalis or a cDNA from Porphyromonas gingivalis.

The invention provides methods of modulating an immune system in a vertebrate host for the therapeutic or prophylactic treatment of infection by a first microbial pathogen in a target tissue, comprising administration at an administration site of an effective amount of an antigenic formulation comprising antigenic determinants specific for a second heterologous microbial pathogen.

A method for increase the presentation of ETEC CS6 antigen on a cell surface, comprising the step of contacting cells expressing said antigen with an aqueous solution comprising 0.6-2.2 percent phenol by weight, such that the presentation of said antigen is increased by at least 100%. A method for the manufacture of a killed whole cell vaccine for immunization against CS6-expressing ETEC. Cells and vaccines obtainable by the above methods.

Described herein are dry compositions that can be stored at ambient temperature without major loss of potency.

The present invention provides use of a Pseudomonas aeruginosa vaccine in the manufacture of a medicament for the prevention and treatment of respiratory system disease. The Pseudomonas aeruginosa vaccine of the present invention can effectively prevent and treat pulmonary infection caused by multidrug-resistant Pseudomonas aeruginosa and COPD complicated with Pseudomonas aeruginosa infection by activating the specific immune response of the body. The Pseudomonas aeruginosa vaccine of the present invention can reduce the bacterial load in the immunized subject through the established immunization procedures, thereby providing a technical solution that can effectively prevent pulmonary infection with Pseudomonas aeruginosa, which avoids the technical problems caused by the use of antibiotics such as poor effectiveness, difficulty in curing and proneness to drug resistance in the prior art to a certain degree.

The present invention belongs to the field of microbiology, and particularly relates to membrane vesicles (MVs) isolated from bacteria, and an isolation and preparation system and method for the membrane vesicles, and applications of the membrane vesicles. The bacteria of the present invention comprise Gram-positive bacteria and Gram-negative bacteria. The invention uses ionizing irradiation to irradiate bacteria, and isolates and purifies the produced membrane vesicles. The membrane vesicles prepared can be used as a vaccine, a vaccine adjuvant and/or a pharmaceutical carrier. In addition, the present invention provides a biological composition comprising the membrane vesicles and inactivated bacteria. In addition, the present invention also provides a preparation system, and isolation and purification system for bacterial membrane vesicles and the corresponding method. The membrane vesicles obtained by using the system and method have high yield, high purity and easy to be industrialized.

Disclosed herein are Mycoplasma bovis immunogenic compositions useful in raising an immune response in animals against M. bovis. Also disclosed herein are methods for generating a protective response against infections in mammals caused by M. bovis.

The present invention relates to the composition and method of preparing an immunogen designated as I-spga consisting of a complex antigen prepared from 18 to 26 species of pathogenic microorganisms isolated from patients, inactivated with binary ethyleneamine (BEI) and formalin, diluted in a SPGA immunopotentiator mixed with QS-21 adjuvant. By inoculating the hens with the I-spga immunogen, hyperimmune eggs (Immunospga) are obtained which contain immunologically active proteins specific to the 18-26 antigens used for immunization. The immune response of the hens is specific to the used antigens by amplification of the antigenic signal by the SPGA immunopotentiator and due to a special immunization program that allows the immune system to act complex and intense: The I-spga complex antigen contains 18-26 microorganisms isolated from patients, bacterial bodies, components from bodies obtained by ultrasonography, cilia, exotoxins, endotoxins, spores, viruses, fungi or yeasts. This pathogenic material is inactivated with BEI and formalin. The I-spga antigen is of three types. The standard I-spga antigen is composed of 18 to 24 antibiotic-resistant bacterial species isolated from patients in Romania. The specific I-spga complex antigen is composed of the I-spga complex antigen containing a mixture of 7-9 strains from a single species of bacteria, fungi or yeasts isolated from patients in Romania mixed with SPGA and QS-21, used for inoculation of hens previously immunized with standard I-spga antigen. The personalized I-spga antigen is composed of patient-derived pathological material containing cellular debris and pathogenic germs inactivated with BEI and formalin and mixed with SPGA and QS-21 and is used to immunize hens previously immunized with the standard I-spga antigen. This now patented technology encompasses a new generation of biological products in which the immune response of the hens to different groups of parenterally inoculated antigens at different time intervals is overlapping. Chicken response is uniform and additional administration of immunogens and SPGA as an immunopotentiator amplifies the antigenic signal and immune response. The I-spga immunogen as well as the immune response contain two markers, G and A, which identify the I-spga antigen used for immunization against the antigens used to produce the Imunoinstant group bio-preparations or similar products. The I-spga immunogen is used to immunize the hens for obtaining immunologically active proteins that can be used to treat immune deficiencies, psoriasis, epidermolysis bullosa, other dermatitises, nosocomial infections, antibiotic-resistant infections in the urinary system of children

A heat killed Porphyromonas gingivalis bacterium expressing a homogenous lipid A structure having a molecular negative mass ion of 1368, 1435/1449, or 1690/1768 is used as an immunomodulator. The immunomodulator may be used in combination with an antigen of interest to potentiate or restrain a host immune response toward the selected antigen.

Methods of treating or preventing stress, anxiety, or postoperative cognitive dysfunction. Also provided are methods of improving resilience in a subject by administering a therapeutically effective amount of isolated Mycobacterium.