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Abstract

Objective

We demonstrated that the tactile mapping system (TMS) has a high degree of spatial precision in the distribution mapping of surface elasticity of tissues or organs.

Methods

Samples used were a circumferential section of a small-caliber porcine artery (diameter: ~3 mm) and an elasticity test pattern with a line and space configuration for the distribution mapping of elasticity, prepared by regional micropatterning of a 14-μm thick gelatin hydrogel coating on a polyurethane sheet. Surface topography and elasticity in normal saline were simultaneously investigated by TMS using a probe with a diameter of 5 or 12 μm, a spatial interval of 1 to 5 μm, and an indentation depth of 4 μm.

Results

In the test pattern, a spatial resolution in TMS of <5 μm was acquired under water with a minimal probe diameter and spatial interval of the probe movement. TMS was used for the distribution mapping of surface elasticity in a flat, circumferential section (thickness: ~0.5 mm) of a porcine artery, and the concentric layers of the vascular wall, including the collagen-rich and elastin-rich layers, could be clearly differentiated in terms of surface elasticity at the spatial resolution of <2 μm.

Conclusions

TMS is a simple and inexpensive technique for the distribution mapping of the surface elasticity in vascular tissues at the spatial resolution <2 μm. TMS has the ability to analyze a complex structure of the tissue samples under normal saline.

Keywords

Tactile mapping system Elasticity image Resolution Vascular tissue Extracellular matrix

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References

Taatjes

D.J.

, Wadsworth

M.P.

, Quinn

A.S.

Imaging aspects of cardiovascular disease at the cell and molecular level. Histochem Cell Biol. 2008; 130: 235–245.

Zoumi

, Lu

, Kassab

G.S.

, Tromberg

B.J.

Imaging coronary artery microstructure using second-harmonic and two-photon fluorescence microscopy. Biophys J. 2004; 87: 2778–2786.

Diaspro

, Bianchini

, Vicidomini

Multi-photon excitation microscopy. Biomed Eng Online. 2006; 5: 1–14.

Wojcikiewicz

E.P.

, Zhang

, Moy

V.T.

Force and compliance measurements on living cells using atomic force microscopy 1 (AFM). Biol Proced Online. 2003; 6: 1–9.

Pesen

, Hoh

J.H.

Micromechanical architecture of the endothelial cell cortex. Biophys J. 2005; 88: 670–679.

Engler

A.J.

, Richert

, Wong

J.Y.

Surface probe measurements of the elasticity of sectioned tissue, thin gels and polyelectrolyte multilayer films: correlations between substrate stiffness and cell adhesion. Surface Sci. 2004; 570: 142–154.

McDaniel

D.P.

, Shaw

G.A.

, Elliott

J.T.

The stiffness of collagen fibrils influences vascular smooth muscle cell phenotype. Biophys J. 2007; 92: 1759–1769.

Wenger

M.P.

, Bozec

, Horton

M.A.

, Mesquida

Mechanical properties of collagen fibrils. Biophys J. 2007; 93: 1255–1263.

Stolz

, Raiteri

, Daniels

A.U.

Dynamic elastic modulus of porcine articular cartilage determined at two different levels of tissue organization by indentation-type atomic force microscopy. Biophys J. 2004; 86: 3269–3283.

10.

Murayama

, Constantinou

C.E.

, Omata

Development of tactile mapping system for the stiffness characterization of tissue slice using novel tactile sensing technology. Sensor Actuat A. 2005; 120: 543–549.

11.

Murayama

, Omata

Fabrication of micro-tactile sensor for the measurement of micro-scale local elasticity. Sensor Actuat A. 2004; 109: 202–207.

12.

Oie

, Murayama

, Fukuda

Local elasticity imaging of vascular tissues by tactile mapping system. J Artif Organs. 2009; 12: 40–46.

13.

Murayama

, Omata

, Constantinou

C.E.

Micro-mechanical sensing platform for the characterization of the elastic properties of the ovum via uniaxial measurement. J Biomech. 2004; 37: 67–72.

14.

Miyazaki

, Hasegawa

, Hayashi

A newly designed tensile tester for cells and its application to fibroblasts. J Biomech. 2000; 33: 97–104.

15.

Kusaka

, Harihara

, Torzilli Objective evaluation of liver consistency to estimate hepatic fibrosis and functional reserve 1 for hepatectomy. J Am Coll Surg. 2000; 1: 47–53.

16.

Eltaib

M.E.

, Hewit

J.R.

Tactile sensing technology for minimal access surgery—a review. Mechatronics. 2003; 13: 1163–1177.

17.

Nakayama

, Matsuda

Photocurable surgical tissue adhesive glues composed of photoreactive gelatin and poly(ethylene glycol) diacrylate. J Biomed Mater Res. 1999; 48: 511–521.

18.

Watanabe

, Kanda

, Ishibashi-Umeda

Development of biotube vascular grafts incorporating cuffs for easy implantation. J Artif Organs. 2007; 10: 10–15.

19.

Sakai

, Kanda

, Ishibashi-Ueda

Development of the wing-attached rod for acceleration of “Biotube” vascular grafts fabrication in vivo. J Biomed Mater Res. 2007; 83: 240–247.

20.

Hayashida

, Kanda

, Yaku

Development of an in vivo tissue-engineered autologous heart valve (the Biovalve): preparation of prototype model. J Thorac Cardiovasc Surg. 2007; 134: 152–159.

21.

Schmidt

, Mol

, Kelm

J.M.

, Hoerstrup

S.P.

In vitro heart valve tissue engineering. Methods Mol Med. 2007; 140: 319–330.

22.

L'Heureux

, McAllister

T.N.

, de la Fuente

L.M.

Tissue-engineered blood vessel for adult arterial revascularization. N Engl J Med. 2007; 357: 1451–1453.

Tactile Mapping System

Abstract

Objective

Methods

Results

Conclusions

Keywords

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References