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Pluripotent embryonic-like stem cells derived from teeth and uses thereof

a stem cell and embryonic technology, applied in the field of embryonic-like stem cells derived from teeth, can solve the problems of reducing the ability to regenerate most human tissues damaged or lost due to trauma or disease in adults, and achieve the effects of stimulating phenotypic expression, increasing the number of differentiated types, and specialized functions

Inactive Publication Date: 2005-05-19
STIFTUNG CAESAR
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Benefits of technology

[0004] The invention enables the skilled person to identify, separate and to build teeth like and teeth related organs and tissues by tissue engineering. The surprisingly advantage of the invention is the preferred use of follicle cells of wisdom teeth, which are routinely extracted in adults and children. Thus, a source of stem cells was developed which freely available even for any adult patients. In contrast to the described stem cells above, these said stem cells are differentiable into a periodontal ligament related biological membrane.
[0005] A Stem Cell can replicate itself and produce cells that take on more specialized functions. The function adopted by the more differentiated daughter cells and their progeny is commonly referred to as the developmental potential, or potency, of the stem cells. Stem cells that give rise to only one type differentiated cell are termed unipotent. In common usage, the relative terms oligopotent, multipotent, and pluripotent represent an increase in the number of differentiated types from new to many or most. A totipotent cell is one that can generate the totality of cell types that can comprise the organism. In practice, these few terms poorly describe a continuum of possibilities.
[0006] The ability to form a wide variety of cell types makes pluripotent stem cells a promising resource for tissue engineering and transplantation. Through the use of enrichment, selection, expression, and sorting technologies, in vitro differentiation of stem cells will certainly contribute to future transplantation therapies.
[0007] Multipotent stem cells can be cultured from a number of foetal and adult sources.
[0008] Perhaps the best known source is bone marrow, which contains both haematopoietic stem cells (Civin et al., 1984) and mesenchymal stem cells (Pittenger et al., 1999). Neural stem cells have also been cultured from the ependymal cells lining the brain ventricles (Johansson et al., 1999a). It is likely that of the many lineage-restricted stem cell populations that exist in vivo, some will be amenable to in vitro growth and analysis.
[0009] The organization of the embryo into three layers roughly corresponds to the organization of the adult, with gut on the inside, epidermis on the outside, and connective tissue in between. The endoderm is the source of the epithelial linings of the respiratory passages and gastrointestinal tract and gives rise to the pharynx, oesophagus, stomach, intestine and to many associated glands, including salivary glands, liver, pancreas and lungs. The mesoderm gives rise to smooth muscular coats, connective tissues, and vessels associated with the tissues and organs; mesoderm also forms most of the cardiovascular system and is the source of blood cells and bone marrow, the skeleton, striated muscles, and the reproductive and excretory organs. Ectoderm will form the epidermis (epidermal layer of the skin), the sense organs, and the entire nervous system, including brain, spinal cord, and all the outlying components of the nervous system.

Problems solved by technology

The formation of tissues and organs occurs naturally in early normal human development, however, the ability to regenerate most human tissues damaged or lost due to trauma or disease is substantially diminished in adults.

Method used

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  • Pluripotent embryonic-like stem cells derived from teeth and uses thereof
  • Pluripotent embryonic-like stem cells derived from teeth and uses thereof
  • Pluripotent embryonic-like stem cells derived from teeth and uses thereof

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Tissue Engineered on Biodegradable Polymer Scaffolds

[0242] We fabricated biodegradable scaffolds in the shape of human molars, seeded them with stem cells derived from stem cells cultured in D-MEM serumreplacement media (GIBCO / BRL) supplemented with 2 mM L-glutamine / 100 units / ml penicillin / 100 μg / ml streptomycin (Biofldids, Rockville, Md.), and implanted the cell / polymer constructs in a cell rotation reactor type from Syntecon, Rotary Cell Culture System RCCS-D, with 50 ml vessel (D-405). A microporous PLLA cell / polymer construct isolated 6 weeks post-implantation had a cell layer adjacent to the polymer.

[0243] Our approach for future therapeutic application is the transplantation of resorbable polymeric scaffolds colonized with stem cells for the periodontium or bone tissue.

[0244] We investigated biochemical and physicochemical parameters of two different polylactid polymer matrices (PLLA, RG 207 Boehringer Ingelheim FRG): biocompatibility, growth of periodontal cells, degradat...

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Abstract

A stem cell which is obtainable from the non-embryonic tissue isolated from the dental follicle of tooth or wisdom tooth which are able to differentiate into a periodontal ligament like membrane structure.

Description

[0001] This invention relates generally to pluripotent stem cells, including embryonic-like pluripotent stem cells derived from teeth. The invention also relates to uses of the stem cells for tissue engineering in cell or tissue transplantation, in gene therapy, and in identifying, assaying or screening with respect to cell-cell interactions, lineage commitment, development genes and growth or differentiation factors. BACKGROUND OF THE INVENTION Stem Cell Location [0002] Any tissue or organ in stasis or undergoing repair and having a connective tissue compartment, has resident populations of mesenchymal stem cells. Organs, tissues and their associated connective tissue components assayed to date include whole embryo, whole foetus, skeletal muscle, dermis, fat, tendon, ligament, perichondrium, periosteurn, heart, aorta, endocardium, myocardium, epicardium, large arteries and veins, granulation tissue, peripheral nerves, peripheral ganglia, spinal cord, dura, leptomeninges, trachea, ...

Claims

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Application Information

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Patent Type & Authority Applications(United States)
IPC IPC(8): A61K31/7105A61K31/711A61K35/12A61K48/00A61P1/02A61P9/00A61P17/00A61P19/00A61P21/00A61P25/00A61P43/00C12N5/074C12N5/077C12N5/10C12N15/09C12Q1/02C12Q1/68G01N33/15G01N33/50
CPCA61K35/12C12N5/0607C12N5/0664C12N2500/38C12N2501/39C12N2503/02G01N33/5073C12N2533/00C12N2533/40G01N33/5008G01N33/5017G01N33/502G01N33/5044C12N2510/00A61P1/02A61P17/00A61P19/00A61P21/00A61P25/00A61P43/00A61P9/00
Inventor SCHIERHOLZ, JOERGZEILHOFER, HANS-FLORIANHOFFMAN, KARL-HEIZMORSCZEXK, CHRISTIANBRENNER, NORBERT
Owner STIFTUNG CAESAR
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