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Abstract

Chondrocyte viability is a crucial factor for evaluating cartilage health. Most prevalent cell viability assays rely on dyes and are not applicable for in vivo or longitudinal studies. Here we demonstrated that the two-photon excited autofluorescence and second harmonic generation microscopy provided high-resolution imaging of cartilage tissue and distinguished live/dead chondrocytes by visual assessment. Furthermore, the normalized autofluorescence ratio was proposed as a quantitative indicator to determine chondrocyte viability. Based on the indicator, a curve fitting and simulated receiver operating characteristic method was proposed to identify the live/dead cell populations as well as the indicator threshold without dye labeling. Thus, it established the label-free imaging method for chondrocyte viability assay in cartilage tissue.

Impact statement

Chondrocytes are the only cellular component found in the cartilage, playing a critical role in maintaining the homeostasis of articular cartilage. The viability of chondrocytes is a crucial factor for evaluating cartilage health. However, the current prevalent cell viability assays rely on dye staining and thereby are not applicable in vivo or in longitudinal assessments. In this study, we demonstrate that the intrinsic signals such as two-photon excited autofluorescence and second harmonic generation can be used to classify live and dead chondrocytes in cartilage tissue. A quantitative measure is also proposed allowing development of automated assessment algorithms. The nonlabeling nature of this method suggests the potential applicability to nondestructive and in vivo assessment of cartilage health.

Keywords

Chondrocyte viability CARTILAGE label-free tissue imaging nonlinear optical microscopy second harmonic generation microscopy autofluorescence

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References

Muir

The chondrocyte, architect of cartilage. Biomechanics, structure, function and molecular biology of cartilage matrix macromolecules. Bioessays 1995; 17:1039–48

Cisternas

Murphy

Sacks

Solomon

Pasta

Helmick

CG.

Alternative methods for defining osteoarthritis and the impact on estimating prevalence in a US population‐based survey. Arthritis Care Res 2016; 68:574–80

Anderson

Chubinskaya

Guilak

Martin

Oegema

Olson

Buckwalter

JA.

Post‐traumatic osteoarthritis: improved understanding and opportunities for early intervention. J Orthopaed Res 2011; 29:802–9

Lotz

MK.

New developments in osteoarthritis: posttraumatic osteoarthritis: pathogenesis and pharmacological treatment options. Arthritis Res Ther 2010; 12:211

Topoluk

Steckbeck

Siatkowski

Burnikel

Tokish

Mercuri

Amniotic mesenchymal stem cells mitigate osteoarthritis progression in a synovial macrophage‐mediated in vitro explant coculture model. J Tissue Eng Regen Med 2018; 12:1097–110

LaPrade

Botker

Herzog

Agel

Refrigerated osteoarticular allografts to treat articular cartilage defects of the femoral condyles: a prospective outcomes study. J Bone Joint Surg Am 2009; 91:805–11

Brockbank

Rahn

Wright

Chen

Yao

Impact of hypothermia upon chondrocyte viability and cartilage matrix permeability after 1 month of refrigerated storage. Transfus Med Hemother 2011; 38:387–92

Bush

Hodkinson

Hamilton

Hall

AC.

Viability and volume of in situ bovine articular chondrocytes – changes following a single impact and effects of medium osmolarity. Osteoarthr Cartil 2005; 13:54–65

Novakofski

Williams

Fortier

Mohammed

Zipfel

Bonassar

LJ.

Identification of cartilage injury using quantitative multiphoton microscopy. Osteoarthr Cartil 2014; 22:355–62

10.

Chen

C-T

Burton-Wurster

Borden

Hueffer

Bloom

Lust

Chondrocyte necrosis and apoptosis in impact damaged articular cartilage. J Orthop Res 2001; 19:703–11

11.

Aigner

Hemmel

Neureiter

Gebhard

Zeiler

Kirchner

McKenna

Apoptotic cell death is not a widespread phenomenon in normal aging and osteoarthritic human articular knee cartilage: a study of proliferation, programmed cell death (apoptosis), and viability of chondrocytes in normal and osteoarthritic human knee cartilage. Arthritis Rheum 2001; 44:1304–12

12.

Wright

McCrum

Tranovich

Huard

Significant chondrocyte viability is present in acetabular chondral flaps associated with femoroacetabular impingement. Am J Sports Med 2018; 46:149–52

13.

Chance

Optical method. Annu Rev Biophys Biophys Chem 1991; 20:1–30

14.

Masters

BR.

Noninvasive redox fluorometry: how light can be used to monitor alterations of corneal mitochondrial function. Curr Eye Res 1984; 3:23–6

15.

Huang

Heikal

Webb

WW.

Two-photon fluorescence spectroscopy and microscopy of NAD (P) H and flavoprotein. Biophys J 2002; 82:2811–25

16.

Liang

W-L

Liu

Z-H

Mei

Y-J

Cai

R-X

Shen

Study the oxidative injury of yeast cells by NADH autofluorescence. Spectrochim Acta Part A 2007; 67:355–9

17.

Pogue

Pitts

Mycek

Sloboda

Wilmot

Brandsema

O'Hara

JA.

In vivo NADH fluorescence monitoring as an assay for cellular damage in photodynamic therapy. Photochem Photobiol 2001; 74:817–24

18.

Eng

Lynch

Balaban

RS.

Nicotinamide adenine dinucleotide fluorescence spectroscopy and imaging of isolated cardiac myocytes. Biophys J 1989; 55:621–30

19.

Dittmar

Potier

van Zandvoort

Ito

Assessment of cell viability in three-dimensional scaffolds using cellular auto-fluorescence. Tissue Eng Part C Methods 2011; 18:198–204

20.

Hennings

Kaufmann

Griffin

Siegel

Novak

Corry

Moros

Shafirstein

Dead or alive? Autofluorescence distinguishes heat-fixed from viable cells. Int J Hyperthermia 2009; 25:355–63

21.

Mertz

Introduction to optical microscopy. Englewood, CO: Roberts, 2010

22.

Sturges

HA.

The choice of a class interval. J Am Stat Assoc 1926; 21:65–6

23.

Marcu

Cohen

Maarek

J-M

Grundfest

WS.

Characterization of type I, II, III, IV, and V collagens by time-resolved laser-induced fluorescence spectroscopy. Optical Biopsy III: International Society for Optics and Photonics, 2000, pp.93–101

24.

Croce

Bottiroli

Autofluorescence spectroscopy and imaging: a tool for biomedical research and diagnosis. Eur J Histochem 2014; 58:2461–78

25.

Lutz

Sattler

Gallinat

Wenck

Poertner

Fischer

Characterization of fibrillar collagen types using multi‐dimensional multiphoton laser scanning microscopy. Int J Cosmet Sci 2012; 34:209–15

26.

Zweig

Campbell

Receiver-operating characteristic (ROC) plots: a fundamental evaluation tool in clinical medicine. Clin Chem 1993; 39:561–77

27.

Lightfoot

Martin

Amendola

Fluorescent viability stains overestimate chondrocyte viability in osteoarticular allografts. Am J Sports Med 2007; 35:1817–23

28.

Eyre

Weis

J-J.

Articular cartilage collagen: an irreplaceable framework. Eur Cell Mater 2006; 12:57–63

29.

Xue

Duan

Sun

Gan

Huang

JY.

Multimodal nonlinear optical microscopy reveals critical role of kinesin-1 in cartilage development. Biomed Opt Express 2017; 8:1771–82

30.

Quinn

Sridharan

Hayden

Kaplan

Lee

Georgakoudi

Quantitative metabolic imaging using endogenous fluorescence to detect stem cell differentiation. Sci Rep 2013; 3:3432

31.

Skala

Riching

Gendron-Fitzpatrick

Eickhoff

Eliceiri

White

Ramanujam

In vivo multiphoton microscopy of NADH and FAD redox states, fluorescence lifetimes, and cellular morphology in precancerous epithelia. Proc Natl Acad Sci U S A 2007; 104:19494–9

32.

Huang

Zheng

Xie

Chen

Zeng

McLean

Lui

Laser-induced autofluorescence microscopy of normal and tumor human colonic tissue. Int J Oncol 2004; 24:59–63

33.

Palmer

Keely

Breslin

Ramanujam

Autofluorescence spectroscopy of normal and malignant human breast cell lines. Photochem Photobiol 2003; 78:462–9

34.

Pavlova

Williams

El-Naggar

Richards-Kortum

Gillenwater

Understanding the biological basis of autofluorescence imaging for oral cancer detection: high-resolution fluorescence microscopy in viable tissue. Clin Cancer Res 2008; 14:2396–404

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Nonlabeling and quantitative assessment of chondrocyte viability in articular cartilage with intrinsic nonlinear optical signatures

Abstract

Impact statement

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