Literature DB >> 20504065

Stereolithographic bone scaffold design parameters: osteogenic differentiation and signal expression.

Kyobum Kim1, Andrew Yeatts, David Dean, John P Fisher.   

Abstract

Scaffold design parameters including porosity, pore size, interconnectivity, and mechanical properties have a significant influence on osteogenic signal expression and differentiation. This review evaluates the influence of each of these parameters and then discusses the ability of stereolithography (SLA) to be used to tailor scaffold design to optimize these parameters. Scaffold porosity and pore size affect osteogenic cell signaling and ultimately in vivo bone tissue growth. Alternatively, scaffold interconnectivity has a great influence on in vivo bone growth but little work has been done to determine if interconnectivity causes changes in signaling levels. Osteogenic cell signaling could be also influenced by scaffold mechanical properties such as scaffold rigidity and dynamic relationships between the cells and their extracellular matrix. With knowledge of the effects of these parameters on cellular functions, an optimal tissue engineering scaffold can be designed, but a proper technology must exist to produce this design to specification in a repeatable manner. SLA has been shown to be capable of fabricating scaffolds with controlled architecture and micrometer-level resolution. Surgical implantation of these scaffolds is a promising clinical treatment for successful bone regeneration. By applying knowledge of how scaffold parameters influence osteogenic cell signaling to scaffold manufacturing using SLA, tissue engineers may move closer to creating the optimal tissue engineering scaffold.

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Year:  2010        PMID: 20504065      PMCID: PMC2962858          DOI: 10.1089/ten.TEB.2010.0171

Source DB:  PubMed          Journal:  Tissue Eng Part B Rev        ISSN: 1937-3368            Impact factor:   6.389


  140 in total

1.  Optimal design and fabrication of scaffolds to mimic tissue properties and satisfy biological constraints.

Authors:  S J Hollister; R D Maddox; J M Taboas
Journal:  Biomaterials       Date:  2002-10       Impact factor: 12.479

Review 2.  Solid freeform fabrication of three-dimensional scaffolds for engineering replacement tissues and organs.

Authors:  K F Leong; C M Cheah; C K Chua
Journal:  Biomaterials       Date:  2003-06       Impact factor: 12.479

3.  Design of tissue engineering scaffolds as delivery devices for mechanical and mechanically modulated signals.

Authors:  Eric J Anderson; Melissa L Knothe Tate
Journal:  Tissue Eng       Date:  2007-10

4.  Dynamics of gene expression during bone matrix formation in osteogenic cultures derived from human embryonic stem cells in vitro.

Authors:  Elerin Kärner; Carl-Magnus Bäckesjö; Jessica Cedervall; Rachael V Sugars; Lars Ahrlund-Richter; Mikael Wendel
Journal:  Biochim Biophys Acta       Date:  2008-10-25

5.  Poly(propylene fumarate) bone tissue engineering scaffold fabrication using stereolithography: effects of resin formulations and laser parameters.

Authors:  Kee-Won Lee; Shanfeng Wang; Bradley C Fox; Erik L Ritman; Michael J Yaszemski; Lichun Lu
Journal:  Biomacromolecules       Date:  2007-02-28       Impact factor: 6.988

6.  Chemical, modulus and cell attachment studies of reactive calcium phosphate filler-containing fast photo-curing, surface-degrading, polymeric bone adhesives.

Authors:  E A Abou Neel; G Palmer; J C Knowles; V Salih; A M Young
Journal:  Acta Biomater       Date:  2010-01-18       Impact factor: 8.947

7.  Porosity and pore size of beta-tricalcium phosphate scaffold can influence protein production and osteogenic differentiation of human mesenchymal stem cells: an in vitro and in vivo study.

Authors:  Philip Kasten; Ingo Beyen; Philipp Niemeyer; Reto Luginbühl; Marc Bohner; Wiltrud Richter
Journal:  Acta Biomater       Date:  2008-06-11       Impact factor: 8.947

8.  In vitro chondrogenesis of bone marrow-derived mesenchymal stem cells in a photopolymerizing hydrogel.

Authors:  Christopher G Williams; Tae Kyun Kim; Anya Taboas; Athar Malik; Paul Manson; Jennifer Elisseeff
Journal:  Tissue Eng       Date:  2003-08

9.  Fabrication and characterization of poly(propylene fumarate) scaffolds with controlled pore structures using 3-dimensional printing and injection molding.

Authors:  Kee-Won Lee; Shanfeng Wang; Lichun Lu; Esmaiel Jabbari; Bradford L Currier; Michael J Yaszemski
Journal:  Tissue Eng       Date:  2006-10

10.  The osteogenic transcription factor Runx2 regulates components of the fibroblast growth factor/proteoglycan signaling axis in osteoblasts.

Authors:  Nadiya M Teplyuk; Larisa M Haupt; Ling Ling; Christian Dombrowski; Foong Kin Mun; Saminathan S Nathan; Jane B Lian; Janet L Stein; Gary S Stein; Simon M Cool; Andre J van Wijnen
Journal:  J Cell Biochem       Date:  2009-05-01       Impact factor: 4.429
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  41 in total

Review 1.  Coculture strategies in bone tissue engineering: the impact of culture conditions on pluripotent stem cell populations.

Authors:  Sathyanarayana Janardhanan; Martha O Wang; John P Fisher
Journal:  Tissue Eng Part B Rev       Date:  2012-07-09       Impact factor: 6.389

Review 2.  Vascularized bone tissue engineering: approaches for potential improvement.

Authors:  Lonnissa H Nguyen; Nasim Annabi; Mehdi Nikkhah; Hojae Bae; Loïc Binan; Sangwon Park; Yunqing Kang; Yunzhi Yang; Ali Khademhosseini
Journal:  Tissue Eng Part B Rev       Date:  2012-09-04       Impact factor: 6.389

3.  Biodegradable composite scaffolds incorporating an intramedullary rod and delivering bone morphogenetic protein-2 for stabilization and bone regeneration in segmental long bone defects.

Authors:  A M Henslee; P P Spicer; D M Yoon; M B Nair; V V Meretoja; K E Witherel; J A Jansen; A G Mikos; F K Kasper
Journal:  Acta Biomater       Date:  2011-06-30       Impact factor: 8.947

Review 4.  Stereolithography in tissue engineering.

Authors:  Shelby A Skoog; Peter L Goering; Roger J Narayan
Journal:  J Mater Sci Mater Med       Date:  2013-12-04       Impact factor: 3.896

Review 5.  Scaffold translation: barriers between concept and clinic.

Authors:  Scott J Hollister; William L Murphy
Journal:  Tissue Eng Part B Rev       Date:  2011-09-21       Impact factor: 6.389

Review 6.  The potential impact of bone tissue engineering in the clinic.

Authors:  Ruchi Mishra; Tyler Bishop; Ian L Valerio; John P Fisher; David Dean
Journal:  Regen Med       Date:  2016-08-23       Impact factor: 3.806

Review 7.  3D Printing of Calcium Phosphate Ceramics for Bone Tissue Engineering and Drug Delivery.

Authors:  Ryan Trombetta; Jason A Inzana; Edward M Schwarz; Stephen L Kates; Hani A Awad
Journal:  Ann Biomed Eng       Date:  2016-06-20       Impact factor: 3.934

8.  Multimaterial Dual Gradient Three-Dimensional Printing for Osteogenic Differentiation and Spatial Segregation.

Authors:  Brandon T Smith; Sean M Bittner; Emma Watson; Mollie M Smoak; Luis Diaz-Gomez; Eric R Molina; Yu Seon Kim; Carrigan D Hudgins; Anthony J Melchiorri; David W Scott; K Jane Grande-Allen; James J Yoo; Anthony Atala; John P Fisher; Antonios G Mikos
Journal:  Tissue Eng Part A       Date:  2019-12-27       Impact factor: 3.845

9.  Effect of scaffold microarchitecture on osteogenic differentiation of human mesenchymal stem cells.

Authors:  Ameya Phadke; YongSung Hwang; Su Hee Kim; Soo Hyun Kim; Tomonori Yamaguchi; Koichi Masuda; Shyni Varghese
Journal:  Eur Cell Mater       Date:  2013-01-18       Impact factor: 3.942

10.  Structural and molecular micropatterning of dual hydrogel constructs for neural growth models using photochemical strategies.

Authors:  Elaine L Horn-Ranney; J Lowry Curley; Gary C Catig; Renee M Huval; Michael J Moore
Journal:  Biomed Microdevices       Date:  2013-02       Impact factor: 2.838
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