55 results about "Heterografts" patented technology

The present invention is a porcine animal, tissue, organ, cells and cell lines, which lack any expression of functional alpha 1,3 galactosyltransferase (alpha1,3GT). These animals, tissues, organs and cells can be used in xenotransplantation and for other medical purposes.

The present technology is related to the field of sterilization and decellularization of allografts or xenografts, specifically to processes that achieve effective removal of the cells contained within a vascular tissue matrix and an effective reduction in potential harmful organisms to create grafts suitable for human implantation. In some embodiments, vascular grafts, vascular tissue and / or blood vessels are contacted with cleaning solution under conditions suitable conditions to reduce immune reaction in patients. More specifically, the present technology is directed to sterilization and decellularization of vascular grafts.

The subject of the invention is a sterile, dehydrated acellular implant, which during its rehydration by water or bodily fluids displays anisotropic expansion and can act as a substrate for adhesion, migration and growth of live cells. Collagen structures of the transplant are at least partially denatured through the action of heat or organic solvents, such as lower aliphatic alcohols and ketones, which simultaneously act as preservative and sterilization agents, especially for certain types of viruses. The implant is sterilized by radiation while in an substantially dehydrated state, preferably by accelerated electrons. The transplant can be derived from various animal tissues, especially mammalian tissues, such as human or porcine tissues. The tissues suitable for the invention can be, for example, skin, placenta, pericardium, peritoneum, intestinal wall, tendon, blood vessel, etc. The implant is suitable for use in human and veterinary medicine, for instance as a temporary wound and burn cover, for the repair, substitution and regeneration of tissues, and also as a substrate for laboratory cell cultivation.

The invention provides nucleic acids, peptides, and antibodies for use in applications including diagnosis and therapy. The peptides target lung cancer and were identified by phage display. Targeting phage PC5-2 and synthetic peptide SP5-2 were both able to recognize human pulmonary tumor specimens from lung cancer patients. In SCID mice bearing NSCLC xenografts, the targeting phage was able to target tumor masses specifically. When the peptide was coupled to liposomes containing the anti-cancer drugs vinorelbine or doxorubicin, the efficacy of these drugs against human lung cancer xenografts was improved, the survival rate increased, and the drug toxicity was reduced.

An embodiment of the invention is a method of using a xenograft as a control tissue for histology, comprising staining both a patient and a xenograft-derived control sample under substantially similar staining conditions, and assessing the staining outcomes of the two to determine whether the stain was effective for the patient sample. A xenograft has never been used before in histology as a control, as far as the inventors know. The result of using a xenograft as a control is surprisingly advantageous. First, the cell lines grow and differentiate similarly to a human, taking on the general morphology of a real tissue sample. Second, because the same transformed cell line can be grown limitless times in SCID mice, the xenograft control is highly reproducible, leading to a consistent artificial control that is highly manufacturable and subject to genetic manipulation so that antigens or genetic elements may be embedded in the tissue. Another embodiment of the invention is directed generally to a method of making a tissue control substrate, comprising growing a xenograft from a mammalian transformed cell line in a host animal, removing the xenograft from the host animal, processing the xenograft thereby embedding the xenograft tissue in an embedding medium, and finally affixing the embedded xenograft sample onto a substrate. The substrate is generally a microscope slide. The xenograft control slide can then be stained side-by-side with a specimen sample in an automated slide stainer, and act as a control against which the staining quality can be compared. The xenograft control can also be used as a manual staining control. Determining whether the staining was effective for the patient specimen comprises judging the staining intensity of the xenograft control sample to determine if the expected degree and type of staining were realized in the control. If the expected type (nuclear, membranous, or cytoplasmic) and degree (0-4 scale) of staining are realized during the run, then the xenograft control indicates the staining process and reagents are working properly, and so the result in the patient specimen can be trusted. A further embodiment of the invention is a xenograft-derived control slide for histochemical use, comprising at least one xenograft control sample prepared for histological use, and a sample slide upon which the at least one xenograft control sample is affixed.

The invention relates to a method for producing a tissue matrix for an allotransplantation or a xenotransplantation, according to which, once a biological tissue has been obtained, said tissue is classified, said tissue is treated and the tissue matrix produced is conditioned, all of said steps being implemented in an automated manner inside the same 'classified' reactor. The invention also relates to the reactor allowing the implementation of the method of the invention.

The invention provides a construction method of a malignant neurinoma xenograft mouse model. The method comprises the following steps of: resuscitating a tumor tissue block of a malignant neurinoma patient stored in a liquid nitrogen environment; and carrying out xenogeneic subcutaneous transplantation on the resuscitated tumor tissue block of the patient into immunodeficient mouse bodies under asterile condition. The xenogeneic subcutaneous transplantation comprises the following steps: selecting immunodeficient mice with the age of 2-6 weeks, wherein the sex of the mice is kept consistent with that of the patient; soaking the resuscitated tumor tissue block of the patient in sterile incubation liquid containing fetal calf serum; fixing the mice after anesthesia; implanting the tumor tissue block of the patient under the skin of the mice; suturing incision; and raising the mice to enable tumors in the body of the mice to grow. The method also includes: performing xenogeneic orthotopic transplantation on the cryopreserved and resuscitated tumor tissue block of the patient into immunodeficient mice. According to the invention, the xenograft mice are used for replacing clinical patients to screen different combined medicines, so that the most appropriate medicine is selected, the effectiveness is greatly improved, and the side effects of the medicines are reduced.