Literature DB >> 25281749

Computer aided-designed, 3-dimensionally printed porous tissue bioscaffolds for craniofacial soft tissue reconstruction.

David A Zopf1, Anna G Mitsak2, Colleen L Flanagan2, Matthew Wheeler3, Glenn E Green1, Scott J Hollister4.   

Abstract

OBJECTIVE: To determine the potential of an integrated, image-based computer-aided design (CAD) and 3-dimensional (3D) printing approach to engineer scaffolds for head and neck cartilaginous reconstruction for auricular and nasal reconstruction. STUDY
DESIGN: Proof of concept revealing novel methods for bioscaffold production with in vitro and in vivo animal data.
SETTING: Multidisciplinary effort encompassing 2 academic institutions. SUBJECTS AND METHODS: Digital Imaging and Communications in Medicine (DICOM) computed tomography scans were segmented and utilized in image-based CAD to create porous, anatomic structures. Bioresorbable polycaprolactone scaffolds with spherical and random porous architecture were produced using a laser-based 3D printing process. Subcutaneous in vivo implantation of auricular and nasal scaffolds was performed in a porcine model. Auricular scaffolds were seeded with chondrogenic growth factors in a hyaluronic acid/collagen hydrogel and cultured in vitro over 2 months' duration.
RESULTS: Auricular and nasal constructs with several types of microporous architecture were rapidly manufactured with high fidelity to human patient anatomy. Subcutaneous in vivo implantation of auricular and nasal scaffolds resulted in an excellent appearance and complete soft tissue ingrowth. Histological analysis of in vitro scaffolds demonstrated native-appearing cartilaginous growth that respected the boundaries of the scaffold.
CONCLUSION: Integrated, image-based CAD and 3D printing processes generated patient-specific nasal and auricular scaffolds that supported cartilage regeneration. © American Academy of Otolaryngology—Head and Neck Surgery Foundation 2014.

Entities:  

Keywords:  3-dimensional printing; CAD/CAM; anotia; auricular reconstruction; computer-aided design; computer-aided manufacturing; craniofacial reconstruction; microtia; nasal reconstruction; tissue engineering

Mesh:

Year:  2014        PMID: 25281749      PMCID: PMC4760858          DOI: 10.1177/0194599814552065

Source DB:  PubMed          Journal:  Otolaryngol Head Neck Surg        ISSN: 0194-5998            Impact factor:   3.497


  22 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

2.  Total nasal reconstruction: utility of the free radial forearm fascial flap.

Authors:  Catherine P Winslow; Ted A Cook; Alan Burke; Mark K Wax
Journal:  Arch Facial Plast Surg       Date:  2003 Mar-Apr

Review 3.  Porous scaffold design for tissue engineering.

Authors:  Scott J Hollister
Journal:  Nat Mater       Date:  2005-07       Impact factor: 43.841

4.  Bone tissue engineering using polycaprolactone scaffolds fabricated via selective laser sintering.

Authors:  Jessica M Williams; Adebisi Adewunmi; Rachel M Schek; Colleen L Flanagan; Paul H Krebsbach; Stephen E Feinberg; Scott J Hollister; Suman Das
Journal:  Biomaterials       Date:  2005-01-23       Impact factor: 12.479

5.  In vitro redifferentiation of culture-expanded rabbit and human auricular chondrocytes for cartilage reconstruction.

Authors:  G J van Osch; S W van der Veen; H L Verwoerd-Verhoef
Journal:  Plast Reconstr Surg       Date:  2001-02       Impact factor: 4.730

6.  An image-based approach for designing and manufacturing craniofacial scaffolds.

Authors:  S J Hollister; R A Levy; T M Chu; J W Halloran; S E Feinberg
Journal:  Int J Oral Maxillofac Surg       Date:  2000-02       Impact factor: 2.789

7.  Engineering craniofacial scaffolds.

Authors:  S J Hollister; C Y Lin; E Saito; C Y Lin; R D Schek; J M Taboas; J M Williams; B Partee; C L Flanagan; A Diggs; E N Wilke; G H Van Lenthe; R Müller; T Wirtz; S Das; S E Feinberg; P H Krebsbach
Journal:  Orthod Craniofac Res       Date:  2005-08       Impact factor: 1.826

8.  A new method of total reconstruction of the auricle for microtia.

Authors:  S Nagata
Journal:  Plast Reconstr Surg       Date:  1993-08       Impact factor: 4.730

9.  The correction of mi-rotia with autogenous cartilage grafts: I. The classic deformity.?

Authors:  B Brent
Journal:  Plast Reconstr Surg       Date:  1980-07       Impact factor: 4.730

10.  Tissue engineering auricular reconstruction: in vitro and in vivo studies.

Authors:  Shyh-Jou Shieh; Shinichi Terada; Joseph P Vacanti
Journal:  Biomaterials       Date:  2004-04       Impact factor: 12.479
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  28 in total

Review 1.  Surgical applications of three-dimensional printing: a review of the current literature & how to get started.

Authors:  Don Hoang; David Perrault; Milan Stevanovic; Alidad Ghiassi
Journal:  Ann Transl Med       Date:  2016-12

2.  Pore architecture effects on chondrogenic potential of patient-specific 3-dimensionally printed porous tissue bioscaffolds for auricular tissue engineering.

Authors:  David A Zopf; Colleen L Flanagan; Anna G Mitsak; Julia R Brennan; Scott J Hollister
Journal:  Int J Pediatr Otorhinolaryngol       Date:  2018-07-24       Impact factor: 1.675

3.  From 3-Dimensional Printing to 5-Dimensional Printing: Enhancing Thoracic Surgical Planning and Resection of Complex Tumors.

Authors:  Erin A Gillaspie; Jane S Matsumoto; Natalie E Morris; Robert J Downey; K Robert Shen; Mark S Allen; Shanda H Blackmon
Journal:  Ann Thorac Surg       Date:  2016-05       Impact factor: 4.330

Review 4.  Image once, print thrice? Three-dimensional printing of replacement parts.

Authors:  Timothy M Rankin; Blair A Wormer; John D Miller; Nicholas A Giovinco; Salam Al Kassis; David G Armstrong
Journal:  Br J Radiol       Date:  2018-01-31       Impact factor: 3.039

Review 5.  3D printing in cell culture systems and medical applications.

Authors:  Max J Lerman; Josephine Lembong; Greg Gillen; John P Fisher
Journal:  Appl Phys Rev       Date:  2018-12       Impact factor: 19.162

Review 6.  Bioprinting: From Tissue and Organ Development to in Vitro Models.

Authors:  Carlos Mota; Sandra Camarero-Espinosa; Matthew B Baker; Paul Wieringa; Lorenzo Moroni
Journal:  Chem Rev       Date:  2020-05-14       Impact factor: 60.622

Review 7.  3D printing for clinical application in otorhinolaryngology.

Authors:  Nongping Zhong; Xia Zhao
Journal:  Eur Arch Otorhinolaryngol       Date:  2017-09-19       Impact factor: 2.503

Review 8.  Personalized scaffolding technologies for alveolar bone regenerative medicine.

Authors:  Ning Yu; Trang Nguyen; Young D Cho; Nolan M Kavanagh; Iya Ghassib; William V Giannobile
Journal:  Orthod Craniofac Res       Date:  2019-05       Impact factor: 1.826

9.  Co-culture of adipose-derived stem cells and chondrocytes on three-dimensionally printed bioscaffolds for craniofacial cartilage engineering.

Authors:  Robert J Morrison; Hassan B Nasser; Khaled N Kashlan; David A Zopf; Derek J Milner; Colleen L Flanangan; Matthew B Wheeler; Glenn E Green; Scott J Hollister
Journal:  Laryngoscope       Date:  2018-04-18       Impact factor: 3.325

Review 10.  Auricular reconstruction from rib to 3D printing.

Authors:  Chelsea L Reighard; Scott J Hollister; David A Zopf
Journal:  J 3D Print Med       Date:  2017-12-15
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