ImmunoMethods最新文献

Liposomes can be made target-specific by immobilizing antibodies on their surface against characteristic components of target organ or tissue. Possible schemes of antibody immobilization on liposomes are briefly considered. The use of immunoliposomes for the targeted delivery of diagnostic and therapeutic agents within the cardiovascular system is discussed. Immunoliposomes are shown to be suitable carriers for targeting blood vessel injuries, lung endothelium, and myocardial infarction. The role of polyethylene glycol in the preparation of long-circulation liposomes is investigated, and a hypothesis explaining the mechanism of polymer protective action in terms of physicochemical properties of diluted polymeric solutions is suggested. Polyethylene glycol-coated liposomes are investigated as possible carriers of imaging agents for gamma and MR visualization of different areas of interest in the body, including lymph nodes. The possibility of simultaneous immobilization of protective polymer and antibody on the liposome surface is proved, and the long-circulating targeted immunoliposomes are used for the targeted delivery of radiolabel to necrotic areas in rabbits with experimental myocardial infarction.

Attachment of antibodies to the surface of liposomes was performed to confer specificity for a certain cell or organ expressing the targeted antigenic determinant. These so-called immunoliposomes are expected to be applied as targeted drug carriers. In this article, the literature concerning in vivo studies of the targeting of immunoliposomes to various sites in the body is reviewed. The anatomical, physiological, and pathological constraints and current progress are described. Moreover, perspectives on the therapeutic feasibility of this drug targeting system are discussed.

and The therapy of cancer is, in reality, the design of therapeutic strategies for therapy of metastatic disease. Metastases consist of unique subpopulations of tumor cells that are derived from the primary tumor, colonize distant target organs, and are able to subvert host immune responses, establish necessary angiogenesis, and obtain a sufficient nutrient supply while evolving to become autonomous from homeostatic mechanisms that function within normal, differentiated tissues. Attempts at eradication of metastases by conventional therapies have generally been unsuccessful due to genetic instability and heterogeneity of metastatic tumors; these properties lead to the emergence of tumor cells that are resistant to most conventional treatments. It may be possible to circumvent this heterogeneity by the activation of tissue macrophages to the tumoricidal state. Activated macrophages are able to kill tumor normals while sparing normal tissues, and efficient activation can be achieved by encapsulation of synthetic muramyl tripeptide analogues into multilamellar vesicles composed of phospholipids. Systemic administration of these liposome-encapsulated compounds leads to tumoricidal activation of alveolar and peritoneal macrophages and eradication of established tumor metastasis in numerous animal tumor models, and this form of therapy is enhanced by combination with parenteral administration of cytokines. Phase III clinical trials of recurrent osteosarcoma are currently in progress. Modulation of the tumor microenvironment by activated macrophages may prove to be an additional modality in treatment strategies that combine the use of biological response modifiers with conventional therapies.

Successful use of liposomes as immunological adjuvants in vaccines requires simple, easy to scale up technology capable of high-yield antigen entrapment. Recent work from this laboratory has led to the development of techniques that can generate liposomes of various sizes containing soluble antigens such as proteins or particulate antigens such as whole, live, or attenuated bacteria or viruses. Entrapment of proteins is carried out by the dehydration-rehydration procedure, which entails freeze-drying of a mixture of "empty" small unilamellar vesicles and free antigens. Upon rehydration, the large multilamellar vesicles that are formed incorporate up to 80% of the antigen used. When such liposomes are microfluidized in the presence of nonentrapped material, their size is reduced to about 100 nm in diameter, with much of the originally entrapped antigen still associated with the vesicles. A similar technique applied to the entrapment of particulate antigens (e.g., Bacillus subtilis spores) consists of freeze-drying giant vesicles (4-5 μm in diameter) in the presence of spores. On rehydration and sucrose gradient fractionation of the suspension, up to 27% of the spores used are associated with generated giant liposomes of similar mean size.

The design of an adjuvant for eliciting a thymus-dependent response to LPS, a well-defined thymus-independent antigen, is presented. Hybrid liposomes containing LPS and HA2 peptide from the hemagglutinin protein of influenza virus within the liposome bilayer were prepared (LPS/HA2 liposomes). The HA2 polypeptide contains epitopes recognized by T-helper lymphocytes and T-cytotoxic lymphocytes. Outbred mice immunized with LPS/HA2 liposomes produced anti-LPS-specific IgG responses. IgG subclass analysis indicated that IgG1, IgG2, and IgG3 antibodies were produced by these animals. LPS liposomes (liposomes without HA2) stimulated a T-independent response only. This was demonstrated by the detection of IgG3 but not IgG1 or IgG2 in serum of mice immunized with LPS liposomes. These results support the concept that the simultaneous incorporation into liposomes of a polypeptide with T-cell recognition sites along with a T-independent antigen can lead to the generation of cognate T-cell help for the T-independent antigen. The synthesis and characterization of a neo-lipopolysaccharide T-independent antigen for incorporation in hybrid HA2 liposomes are also presented. Findings are discussed relative to the liposome model used and implications for development of vaccines for use in humans.

A liposome vaccine formulation that has been successfully used in both animal immunization studies and clinical trials is described. Issues concerning the choice of components for the liposomal vaccine formulation are discussed, especially with respect to the lipid components and the adjuvant. A procedure is described for manufacturing liposomal vaccines using Good Manufacturing Practices as promulgated by the U.S. Food and Drug Administration. Quality control testing for clinical use is described, with particular emphasis on aspects relevant to liposomes. Utilization issues are discussed, including injection volumes, antigen and adjuvant doses, and routes of administration.

Different types of liposomes have been employed to deliver soluble antigen for processing and presentation in the major histocompatibility complex class I-restricted pathway. Anionic pH-sensitive liposomes as well as cationic liposomes efficiently sensitize antigen-presenting cells for recognition by the class I-restricted cytotoxic T lymphocytes (CTL). Cytoplasmic delivery of liposome-entrapped antigen from an endocytic compartment allows the exogenous antigen to gain access to the class I presentation pathway. Cytoplasmic delivery, however, is probably not the only mechanism by which liposomes induce the class I-restricted CTL priming in vivo. Macrophages play a central role in the processing of the liposome-encapsulated antigens. The processed antigen fragments are probably released by the macrophages and taken up by the nearby dendritic cells for antigen presentation. Collaboration between the two types of immune cells with the help of the appropriate costimulatory factors is the central theme for this hypothesis. In this case, the host immune system utilizes the similar mechanism for other membranous, particulate antigens to process and present the liposomal antigens.

B cells have limited endocytic capacity and are reported to endocytose and present liposome-encapsulated antigens poorly. B cells also endocytose soluble antigens poorly, except those for which their surface immunoglobulin is specific, which are taken up and presented efficiently. We present results indicating that, in vitro, B cells endocytose small liposomes bearing antigen with affinity for their surface immunoglobulin. Antigen encapsulated in liposomes targeted by antibody specific for surface immunoglobulin is presented to T cells as efficiently as specific antigen in soluble form. These studies provide a rational basis for the design of liposomes optimized to stimulate T-dependent B-cell responses.