Introduction to surgical practice of new technologies for reconstruction and regeneration of damaged tissues in the area of the face (Q83984): Difference between revisions
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(Removed claim: summary (P836): The aim of the project is to develop technologies for obtaining personalised tissue scaffolds:(i) unsprung and (ii) resorptions which will be used for the reconstruction of the facial, inter alia, in the area of the jaw, hard palate, eye socket, jaws.To this end, the following will be developed and combined:(1) a program using which a computer tomography or magnetic resonance background will be used to design the destination grate, (2) the new...) |
(Created claim: summary (P836): The aim of the project is to develop technology of personalised tissue scaffolding: (i) non-resorbable and (ii) resorbable, which will be used in the reconstruction of the face, among others, in the area of maxillo-sit massif, hard palate, eye socket, jaw. To this end, the following will be developed and interconnected: (1) a program using which the data from a computer tomograph or magnetic resonance will be used to design the shape of the scaf...) |
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The aim of the project is to develop technology of personalised tissue scaffolding: (i) non-resorbable and (ii) resorbable, which will be used in the reconstruction of the face, among others, in the area of maxillo-sit massif, hard palate, eye socket, jaw. To this end, the following will be developed and interconnected: (1) a program using which the data from a computer tomograph or magnetic resonance will be used to design the shape of the scaffolding target, (2) a new composite material (2.1) non-biodegradable combination of non-biodegradable polymer materials with organic/inorganic additives (2.2) biodegradable biodegradable cell-based combination of biodegradable polymer material with organic/inorganic additives, and inorganic (2.2) biodegradable biodegradable methods of which the biodegradable polymer material will be used with organic/non-organic additives, and inorganic (2.2) biodegradable methods of biodegradable polymer material with organic/inorganic additives, and the biodegradable methods of which will be produced from the biodegradable polymer material with organic/inorganic additives, and inorganic (2.2) biodegradable biodegradable methods of which are derived from a combination of biodegradable polymer material with organic/inorganic additives, and inorganic (2.2) biodegradable biodegradable methods from the biodegradable polymer material with organic/inorganic additives,3; parent (differentiation) and WAT (transdisting) and methods of colonising scaffolding with target cells (osteoblasts), (5) anatomical models for planning surgical operations. The use of technologies for personalised tissue scaffolding in practice will depend on a clinical case and the decision maker of the choice of the combination of the results of the project will be the surgeon, so the practical use of the reconstructed technology should be considered in terms of: (a) Total – i.e. a combination of all components of the project: program, material, anatomical model, printer and method of obtaining and colonising osteoblasts on scaffolds, (b) partial – as the application/combination of selected project results: program and/or material and/or printer and/or cells and/or anatomical models (English) | |||||||||||||||
Property / summary: The aim of the project is to develop technology of personalised tissue scaffolding: (i) non-resorbable and (ii) resorbable, which will be used in the reconstruction of the face, among others, in the area of maxillo-sit massif, hard palate, eye socket, jaw. To this end, the following will be developed and interconnected: (1) a program using which the data from a computer tomograph or magnetic resonance will be used to design the shape of the scaffolding target, (2) a new composite material (2.1) non-biodegradable combination of non-biodegradable polymer materials with organic/inorganic additives (2.2) biodegradable biodegradable cell-based combination of biodegradable polymer material with organic/inorganic additives, and inorganic (2.2) biodegradable biodegradable methods of which the biodegradable polymer material will be used with organic/non-organic additives, and inorganic (2.2) biodegradable methods of biodegradable polymer material with organic/inorganic additives, and the biodegradable methods of which will be produced from the biodegradable polymer material with organic/inorganic additives, and inorganic (2.2) biodegradable biodegradable methods of which are derived from a combination of biodegradable polymer material with organic/inorganic additives, and inorganic (2.2) biodegradable biodegradable methods from the biodegradable polymer material with organic/inorganic additives,3; parent (differentiation) and WAT (transdisting) and methods of colonising scaffolding with target cells (osteoblasts), (5) anatomical models for planning surgical operations. The use of technologies for personalised tissue scaffolding in practice will depend on a clinical case and the decision maker of the choice of the combination of the results of the project will be the surgeon, so the practical use of the reconstructed technology should be considered in terms of: (a) Total – i.e. a combination of all components of the project: program, material, anatomical model, printer and method of obtaining and colonising osteoblasts on scaffolds, (b) partial – as the application/combination of selected project results: program and/or material and/or printer and/or cells and/or anatomical models (English) / rank | |||||||||||||||
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Property / summary: The aim of the project is to develop technology of personalised tissue scaffolding: (i) non-resorbable and (ii) resorbable, which will be used in the reconstruction of the face, among others, in the area of maxillo-sit massif, hard palate, eye socket, jaw. To this end, the following will be developed and interconnected: (1) a program using which the data from a computer tomograph or magnetic resonance will be used to design the shape of the scaffolding target, (2) a new composite material (2.1) non-biodegradable combination of non-biodegradable polymer materials with organic/inorganic additives (2.2) biodegradable biodegradable cell-based combination of biodegradable polymer material with organic/inorganic additives, and inorganic (2.2) biodegradable biodegradable methods of which the biodegradable polymer material will be used with organic/non-organic additives, and inorganic (2.2) biodegradable methods of biodegradable polymer material with organic/inorganic additives, and the biodegradable methods of which will be produced from the biodegradable polymer material with organic/inorganic additives, and inorganic (2.2) biodegradable biodegradable methods of which are derived from a combination of biodegradable polymer material with organic/inorganic additives, and inorganic (2.2) biodegradable biodegradable methods from the biodegradable polymer material with organic/inorganic additives,3; parent (differentiation) and WAT (transdisting) and methods of colonising scaffolding with target cells (osteoblasts), (5) anatomical models for planning surgical operations. The use of technologies for personalised tissue scaffolding in practice will depend on a clinical case and the decision maker of the choice of the combination of the results of the project will be the surgeon, so the practical use of the reconstructed technology should be considered in terms of: (a) Total – i.e. a combination of all components of the project: program, material, anatomical model, printer and method of obtaining and colonising osteoblasts on scaffolds, (b) partial – as the application/combination of selected project results: program and/or material and/or printer and/or cells and/or anatomical models (English) / qualifier | |||||||||||||||
point in time: 14 October 2020
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Revision as of 16:41, 14 October 2020
Project in Poland financed by DG Regio
Language | Label | Description | Also known as |
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English | Introduction to surgical practice of new technologies for reconstruction and regeneration of damaged tissues in the area of the face |
Project in Poland financed by DG Regio |
Statements
6,294,057.65 zloty
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6,950,848.65 zloty
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90.55 percent
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1 January 2018
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31 December 2020
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ŚLĄSKI UNIWERSYTET MEDYCZNY W KATOWICACH
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Celem projektu jest opracowanie technologii otrzymywania spersonalizowanych rusztowań tkankowych: (i) nieresorbowalnych oraz (ii) resorbowalnych, które znajdą zastosowanie w rekonstrukcji twarzoczaszki m.in. w obszarze masywu szczękowo-sitowego, podniebienia twardego, oczodołu, szczęki. W tym celu opracowany i połączony ze sobą zostanie: (1) program z zastosowaniem którego dane z tomografu komputerowego lub rezonansu magnetycznego wykorzystane zostaną do zaprojektowania kształtu docelowego rusztowania, (2) nowy materiał kompozytowy (2.1) niebiodegradowalny powstały z kombinacji niebiodegradowalnych materiałów polimerowych z dodatkami organicznymi/nieorganicznymi (2.2) biodegradowalny powstały z kombinacji biodegradowalnego materiału polimerowego z dodatkami organicznymi/nieorganicznymi, (3) drukarka SLS z zastosowaniem, której drukowane będą rusztowania niebiodegradowalne oraz biodegradowalne, (4) metody otrzymywania komórek docelowych (osteoblastów) z komórek wyjściowych – macierzystych (różnicowanie) i WAT (transdyferencjacja) oraz metody zasiedlania rusztowań komórkami docelowymi (osteoblastami), (5) modele anatomiczne do planowania operacji chirurgicznych. Wykorzystanie technologii otrzymywania spersonalizowanych rusztowań tkankowych w praktyce, uzależnione będzie od przypadku klinicznego, a decydentem wyboru kombinacji rezultatów projektu będzie chirurg, dlatego praktyczne wykorzystanie opracowanej technologii rekonstrukcji należy rozpatrzyć w ujęciu: (a) całkowitym - tj. połączeniu wszystkich składowych projektu: programu, materiału, modelu anatomicznego, drukarki oraz sposobu otrzymywania osteoblastów i zasiedlania ich na rusztowaniach, (b) częściowym - jako zastosowanie /połączenie wybranych rezultatów projektu: programu i/lub materiału i/lub drukarki i/lub komórek i/lub modeli anatomicznych (Polish)
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The aim of the project is to develop technology of personalised tissue scaffolding: (i) non-resorbable and (ii) resorbable, which will be used in the reconstruction of the face, among others, in the area of maxillo-sit massif, hard palate, eye socket, jaw. To this end, the following will be developed and interconnected: (1) a program using which the data from a computer tomograph or magnetic resonance will be used to design the shape of the scaffolding target, (2) a new composite material (2.1) non-biodegradable combination of non-biodegradable polymer materials with organic/inorganic additives (2.2) biodegradable biodegradable cell-based combination of biodegradable polymer material with organic/inorganic additives, and inorganic (2.2) biodegradable biodegradable methods of which the biodegradable polymer material will be used with organic/non-organic additives, and inorganic (2.2) biodegradable methods of biodegradable polymer material with organic/inorganic additives, and the biodegradable methods of which will be produced from the biodegradable polymer material with organic/inorganic additives, and inorganic (2.2) biodegradable biodegradable methods of which are derived from a combination of biodegradable polymer material with organic/inorganic additives, and inorganic (2.2) biodegradable biodegradable methods from the biodegradable polymer material with organic/inorganic additives,3; parent (differentiation) and WAT (transdisting) and methods of colonising scaffolding with target cells (osteoblasts), (5) anatomical models for planning surgical operations. The use of technologies for personalised tissue scaffolding in practice will depend on a clinical case and the decision maker of the choice of the combination of the results of the project will be the surgeon, so the practical use of the reconstructed technology should be considered in terms of: (a) Total – i.e. a combination of all components of the project: program, material, anatomical model, printer and method of obtaining and colonising osteoblasts on scaffolds, (b) partial – as the application/combination of selected project results: program and/or material and/or printer and/or cells and/or anatomical models (English)
14 October 2020
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Identifiers
POIR.04.01.02-00-0085/17
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