Bioresorbable microspheres by spinning disk atomization as injectable cell carrier: from preparation to in vitro evaluation

Vesico-ureteral reflux, a common pathology in children, can be treated cystoscopically by injection of a bulking material underneath the most distal, intramural ureter, which forces the latter to do a detour, increasing its submucosal path. This increase of the length of the submucosal path of the u...

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Published in:	Biomaterials Vol. 21; no. 11; pp. 1135 - 1144
Main Authors:	Senuma, Y, Franceschin, S, Hilborn, J.G, Tissières, P, Bisson, I, Frey, P
Format:	Journal Article
Language:	English
Published:	Oxford Elsevier Ltd 01-06-2000 Elsevier Science
Subjects:	Absorbable Implants Animals Atomization Biocompatibility Biocompatible Materials Biological and medical sciences Biopolymers Bioresorbable polymer Cell carrier Cells, Cultured Evaluation Studies as Topic Living systems studies Male Medical sciences Microscopy, Electron, Scanning Microspheres Muscle Porous microspheres Radiotherapy. Instrumental treatment. Physiotherapy. Reeducation. Rehabilitation, orthophony, crenotherapy. Diet therapy and various other treatments (general aspects) Rats Rats, Wistar Spinning disk atomization Technology. Biomaterials. Equipments. Material. Instrumentation Temperature control Thermal effects Tissue engineering Urinary Bladder - cytology Vesico-ureteral reflux Cell carrier Bioresorbable polymer Vesico-ureteral reflux Tissue engineering Porous microspheres Spinning disk atomization Cell culture Injectable form Urinary system disease Microsphere Biodegradability Control release polymer Urinary tract disease In vitro Lactic acid polymer Treatment Manufacturing process Vesicoureteral reflux Bladder disease Atomization Biomedical engineering
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Abstract	Vesico-ureteral reflux, a common pathology in children, can be treated cystoscopically by injection of a bulking material underneath the most distal, intramural ureter, which forces the latter to do a detour, increasing its submucosal path. This increase of the length of the submucosal path of the ureter within the bladder is directly responsible for the anti-reflux effect. So far Teflon and collagen paste have been commonly used as bulking materials. We suggest replacing these materials by living tissue consisting of bladder smooth muscle, normally present at this location. The aim of this work is to provide a long-term effective treatment by producing bioresorbable microspheres which can act as a support matrix and an entrapment substance for bladder smooth muscle cells, with the goal of an in vivo transfer of the in vitro cultured cells with a minimal surgical procedure. By the use of Spinning Disk Atomization, which has specifically been developed for this purpose, we have shown two methods for the preparation of porous poly(lactic acid) microspheres with tunable sizes from 160 to 320 μm. The controlled solvent burst method has shown the advantage over the crystal leaching method in the direct creation of microspheres with large closed pores, by atomizing the polymer solution in controlled temperature conditions. Microspheres with various closed pore structures have thus been prepared. The innovation of this work is in the direct and rapid formation of porous microspheres with a pore morphology which is designed to create cavities suitable for adherence and growth of cells by adapting the temperature conditions of atomization. Injection tests have shown promising results in using these cell-loaded microspheres for future non-invasive tissue engineering.
AbstractList	Vesico-ureteral reflux, a common pathology in children, can be treated cystoscopically by injection of a bulking material underneath the most distal, intramural ureter, which forces the latter to do a detour, increasing its submucosal path. This increase of the length of the submucosal path of the ureter within the bladder is directly responsible for the anti-reflux effect. So far Teflon and collagen paste have been commonly used as bulking materials. We suggest replacing these materials by living tissue consisting of bladder smooth muscle, normally present at this location. The aim of this work is to provide a long-term effective treatment by producing bioresorbable microspheres which can act as a support matrix and an entrapment substance for bladder smooth muscle cells, with the goal of an in vivo transfer of the in vitro cultured cells with a minimal surgical procedure. By the use of Spinning Disk Atomization, which has specifically been developed for this purpose, we have shown two methods for the preparation of porous poly(lactic acid) microspheres with tunable sizes from 160 to 320 mu m. The controlled solvent burst method has shown the advantage over the crystal leaching method in the direct creation of microspheres with large closed pores, by atomizing the polymer solution in controlled temperature conditions. Microspheres with various closed pore structures have thus been prepared. The innovation of this work is in the direct and rapid formation of porous microspheres with a pore morphology which is designed to create cavities suitable for adherence and growth of cells by adapting the temperature conditions of atomization. Injection tests have shown promising results in using these cell-loaded microspheres for future non-invasive tissue engineering. Vesico-ureteral reflux, a common pathology in children, can be treated cystoscopically by injection of a bulking material underneath the most distal, intramural ureter, which forces the latter to do a detour, increasing its submucosal path. This increase of the length of the submucosal path of the ureter within the bladder is directly responsible for the anti-reflux effect. So far Teflon and collagen paste have been commonly used as bulking materials. We suggest replacing these materials by living tissue consisting of bladder smooth muscle, normally present at this location. The aim of this work is to provide a long-term effective treatment by producing bioresorbable microspheres which can act as a support matrix and an entrapment substance for bladder smooth muscle cells, with the goal of an in vivo transfer of the in vitro cultured cells with a minimal surgical procedure. By the use of Spinning Disk Atomization, which has specifically been developed for this purpose, we have shown two methods for the preparation of porous poly(lactic acid) microspheres with tunable sizes from 160 to 320 microm. The controlled solvent burst method has shown the advantage over the crystal leaching method in the direct creation of microspheres with large closed pores, by atomizing the polymer solution in controlled temperature conditions. Microspheres with various closed pore structures have thus been prepared. The innovation of this work is in the direct and rapid formation of porous microspheres with a pore morphology which is designed to create cavities suitable for adherence and growth of cells by adapting the temperature conditions of atomization. Injection tests have shown promising results in using these cell-loaded microspheres for future non-invasive tissue engineering. Vesico-ureteral reflux, a common pathology in children, can be treated cystoscopically by injection of a bulking material underneath the most distal, intramural ureter, which forces the latter to do a detour, increasing its submucosal path. This increase of the length of the submucosal path of the ureter within the bladder is directly responsible for the anti-reflux effect. So far Teflon and collagen paste have been commonly used as bulking materials. We suggest replacing these materials by living tissue consisting of bladder smooth muscle, normally present at this location. The aim of this work is to provide a long-term effective treatment by producing bioresorbable microspheres which can act as a support matrix and an entrapment substance for bladder smooth muscle cells, with the goal of an in vivo transfer of the in vitro cultured cells with a minimal surgical procedure. By the use of Spinning Disk Atomization, which has specifically been developed for this purpose, we have shown two methods for the preparation of porous poly(lactic acid) microspheres with tunable sizes from 160 to 320 μm. The controlled solvent burst method has shown the advantage over the crystal leaching method in the direct creation of microspheres with large closed pores, by atomizing the polymer solution in controlled temperature conditions. Microspheres with various closed pore structures have thus been prepared. The innovation of this work is in the direct and rapid formation of porous microspheres with a pore morphology which is designed to create cavities suitable for adherence and growth of cells by adapting the temperature conditions of atomization. Injection tests have shown promising results in using these cell-loaded microspheres for future non-invasive tissue engineering. This work aims to provide a long-term effective treatment of vesico-ureteral reflux by producing bioresorbable microspheres which can act as a support matrix and entrapment substance for bladder smooth muscle cells. An in vivo transfer of the in vitro cultured cells should be possible with minimal surgical procedure. Using spinning disk atomization, specifically developed for this purpose, two methods are shown for the preparation of porous poly(lactic acid) microspheres with tunable sizes of 160-320 \#m\m and various closed pore structures. The pore morphology can be designed by adapting the temperature conditions of atomization. Injection tests using cell-loaded microspheres show promising results.
Author	Hilborn, J.G Tissières, P Franceschin, S Bisson, I Senuma, Y Frey, P
Author_xml	– sequence: 1 givenname: Y surname: Senuma fullname: Senuma, Y organization: Polymer Laboratory, Department of Materials Science, Swiss Federal Institute of Technology Lausanne, CH-1015 Ecublens, Switzerland – sequence: 2 givenname: S surname: Franceschin fullname: Franceschin, S organization: Polymer Laboratory, Department of Materials Science, Swiss Federal Institute of Technology Lausanne, CH-1015 Ecublens, Switzerland – sequence: 3 givenname: J.G surname: Hilborn fullname: Hilborn, J.G email: Joens.Hilborn@epfl.ch organization: Polymer Laboratory, Department of Materials Science, Swiss Federal Institute of Technology Lausanne, CH-1015 Ecublens, Switzerland – sequence: 4 givenname: P surname: Tissières fullname: Tissières, P organization: Pediatric Urology Research Laboratory, Department of Pediatric Surgery, Centre Hospitalier Universitaire Vaudois, Switzerland – sequence: 5 givenname: I surname: Bisson fullname: Bisson, I organization: Pediatric Urology Research Laboratory, Department of Pediatric Surgery, Centre Hospitalier Universitaire Vaudois, Switzerland – sequence: 6 givenname: P surname: Frey fullname: Frey, P organization: Pediatric Urology Research Laboratory, Department of Pediatric Surgery, Centre Hospitalier Universitaire Vaudois, Switzerland
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Keywords	Cell carrier Bioresorbable polymer Vesico-ureteral reflux Tissue engineering Porous microspheres Spinning disk atomization Cell culture Injectable form Urinary system disease Microsphere Biodegradability Control release polymer Urinary tract disease In vitro Lactic acid polymer Treatment Manufacturing process Vesicoureteral reflux Bladder disease Atomization Biomedical engineering
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Snippet	Vesico-ureteral reflux, a common pathology in children, can be treated cystoscopically by injection of a bulking material underneath the most distal,... This work aims to provide a long-term effective treatment of vesico-ureteral reflux by producing bioresorbable microspheres which can act as a support matrix...
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SubjectTerms	Absorbable Implants Animals Atomization Biocompatibility Biocompatible Materials Biological and medical sciences Biopolymers Bioresorbable polymer Cell carrier Cells, Cultured Evaluation Studies as Topic Living systems studies Male Medical sciences Microscopy, Electron, Scanning Microspheres Muscle Porous microspheres Radiotherapy. Instrumental treatment. Physiotherapy. Reeducation. Rehabilitation, orthophony, crenotherapy. Diet therapy and various other treatments (general aspects) Rats Rats, Wistar Spinning disk atomization Technology. Biomaterials. Equipments. Material. Instrumentation Temperature control Thermal effects Tissue engineering Urinary Bladder - cytology Vesico-ureteral reflux
Title	Bioresorbable microspheres by spinning disk atomization as injectable cell carrier: from preparation to in vitro evaluation
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