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Abstract

Both surgical tympanoplasty and paper patch grafts are frequently procedured to heal tympanic membrane (TM) perforation or chronic otitis media, despite their many disadvantages. In this study, we report a new healing method of TM perforation by using three-dimensional (3D) porous chitosan scaffolds (3D chitosan scaffolds) as an alternative method to surgical treatment or paper patch graft. Various 3D chitosan scaffolds were prepared; and the structural characteristics, mechanical property, in vitro biocompatibility, and healing effects of the 3D chitosan scaffolds as an artificial TM in in vivo animal studies were investigated. A 3D chitosan scaffold of 5 wt.% chitosan concentration showed good proliferation of TM cells in an in vitro study, as well as suitable structural characteristics and mechanical property, as compared with either 1% or 3% chitosan. In in vivo animal studies, 3D chitosan scaffold were able to migrate through the pores and surfaces of TM cells, thus leading to more effective TM regeneration than paper patch technique. Histological observations demonstrated that the regenerated TM with the 3D chitosan scaffold consisted of three (epidermal, connective tissue, and mucosal) layers and were thicker than normal TMs. The 3D chitosan scaffold technique may be an optimal healing method used in lieu of surgical tympanoplasty in certain cases to heal perforated TMs.

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References

Gladstone

H.B.

, Jacker

R.K.

, Varav

Tympanic membrane wound healing: an overview. Otolaryngol Clin North Am, 28:913. 1995.

Laidlaw

D.W.

, Costantino

P.D.

, Govindaraj

, Hiltzik

D.H.

, Catalano

P.J.

Tympanic membrane repair with a dermal allograft. Laryngoscope, 111:702. 2001.

Kim

J.H.

, Choi

S.J.

, Park

J.S.

, Lim

K.T.

, Choung

P.H.

, Kim

S.W.

, Lee

J.B.

, Chung

J.H.

, Choung

Y.H.

Tympanic membrane regeneration using a water-soluble chitosan patch. Tissue Eng Part A, 16:225. 2010

Blake

C.J.

Transactions of the First of Congress of the International Otological Society (abstract) New York: D. Appleton and Co., 1887; 125.

Chun

S.H.

, Lee

D.W.

, Shin

J.K.

A clinical study of traumatic tympanic perforation. Korean J Otolaryngol, 23:437. 1999.

Bonzona

, Carrat

, Deminiere

, Daculsi

, Lefebvre

, Rabaud

New artificial connective matrix made of fibrin monomers, elastin peptides and type I+III collagens: structural study, biocompatibility and use as tympanic membranes in rabbit. Biomaterials, 16:881. 1995.

Chauvin

, Bratton

, Parkins

Healing large tympanic membrane perforations using hyaluronic acid, basic fibroblast growth factor, and epidermal growth factor. Otolaryngol Head Neck Surg, 121:43. 1999.

Kohn

F.E.

, Feijen

, Feenstra

New perspectives in myringoplasty. Int J Artif Organs, 7:151. 1984.

Weber

D.E.

, Semaan

M.T.

, Wasman

J.K.

, Beane

, Bonassar

L.J.

, Megerian

C.A.

Tissue-engineered calcium alginate patches in the repair of chronic chinchilla tympanic membrane perforations. Laryngoscope, 116:700. 2006.

10.

Ghassemifar

, Redmond

, Zainuddin , Chirila

T.V.

Advancing towards a tissue-engineered tympanic membrane: silk fibroin as a substratum for growing human eardrum keratinocytes. J Biomater Appl, 24:591. 2010.

11.

Kim

, Kim

C.H.

, Park

C.H.

, Seo

J.N.

, Kweon

H.Y.

, Kang

S.W.

, Lee

K.G.

Comparison of methods for the repair of acute tympanic membrane perforations: silk patch vs. paper patch. Wound Repair Regen, 18:132. 2010.

12.

Kim

J.H.

, Bae

J.H.

, Lim

K.T.

, Choung

P.H.

, Park

J.S.

, Choi

S.J.

, Im

A.L.

, Lee

E.T.

, Choung

Y.H.

, Chung

J.H.

Development of water-insoluble chitosan patch scaffold to repair traumatic tympanic membrane perforations. J Biomed Mater Res A, 90:446. 2009.

13.

Parekh

, Mantle

, Banks

, Swarts

J.D.

, Badylak

S.F.

, Dohar

J.E.

, Hebda

P.A.

Repair of the tympanic membrane with urinary bladder matrix. Laryngoscope, 119:1206. 2009.

14.

Lim

A.A.

, Washington

A.P.

, Greinwald

J.H.

, Lassen

L.F.

, Holterl

M.R.

Effect of pentoxifyline on the healing of guinea pig tympanic membrane. Ann Otol Rhinol Laryngol, 109:262. 2000.

15.

Hakuba

, Iwanaga

, Tanaka

, Hiratsuka

, Kumabe

, Konishi

, Okanoue

, Hiwatashi

, Wada

Basic fibroblast growth factor combined with atelocollagen for closing chronic tympanic membrane perforations in 87 patients. Otol Neurtol, 31:118. 2010.

16.

Hott

M.E.

, Megerian

C.A.

, Beane

, Bonassar

Fabrication of tissue engineered tympanic membrane patches using computer-aided design and injection modeling. Laryngoscope, 114:1290. 2004.

17.

Deng

, Wu

, Qiu

, Wang

, Tian

, Li

, Jin

Comparison of porcine acellular dermis and dura mater as natural scaffolds for bioengineering tympanic membranes. Tissue Eng Part A, 15:3729. 2009.

18.

Ungea

M.V.

, Dirckxb

, Olivius

N.P.

Embryonic stem cells enhance the healing of tympanic membrane perforations. Int J Pediatr Otorhinolaryngol, 67:215. 2003.

19.

Rahman

, Unge

M.V.

, Olivius

, Dirckx

, Hultcrantz

Healing time, long-term result and effects of stem cell treatment in acute tympanic membrane perforation. Int J Pediatr Otorhinolaryngol, 71:1129. 2007.

20.

Rahman

, Olivius

, Dirckxb

, Unge

M.V.

, Hultcrantz

Stem cells and enhanced healing of chronic tympanic membrane perforation. Acta Otolaryngol, 128:352. 2008.

21.

Kim

I.Y.

, Seo

S.J.

, Moon

H.S.

, Park

I.Y.

, Kim

B.C.

, Cho

C.S.

Chitosan and its derivatives for tissue engineering applications. Biothechnol Adv, 26:1. 2008.

22.

Rinaudo

Chitin and chitosan: properties and applications. Prog Polym Sci, 31:603. 2006.

23.

Chen

C.L.

, Wang

Y.M.

, Liu

C.F.

, Wang

J.Y.

The effect of water-soluble chitosan on macrophage activation and the attenuation of mite allergen-induced airway inflammation. Biomaterials, 29:2173. 2008.

24.

Madihally

S.V.

, Matthew

W.T.

Porous chitosan scaffolds for tissue engineering. Biomaterials, 20:1133. 1999.

25.

Huang

, Onyeri

, Siewe

, Moshfeghian

, Madihally

S.V.

In vitro characterization of chitosan-gelatin scaffolds for tissue engineering. Biomaterials, 26:7616. 2005.

26.

Hsieh

W.C.

, Chang

C.P.

, Lin

S.M.

Morphology and characterization of 3D micro-porous structured chitosan scaffolds for tissue engineering. Colloids Surf B Biointerfaces, 57:250. 2007.

27.

Choi

S.J.

, Kim

W.S.

, Kim

J.H.

, Lee

J.B.

, Choo

O.S.

, Chung

J.H.

, Choung

Y.H.

Efficient treatment of chronic tympanic membrane perforations in animal models by chitosan patch scaffolds. Tissue Eng Regen Med, 8:141. 2011.

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A Healing Method of Tympanic Membrane Perforations Using Three-Dimensional Porous Chitosan Scaffolds

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