Automated cardiac sarcomere analysis from second harmonic generation images

Garcia-Canadilla, Patricia; Gonzalez-Tendero, Anna; Iruretagoyena, Igor; Crispi, F.; Torre, Iratxe; Amat-Roldán, Ivan; Bijnens, Bart; Gratacós, Eduard

doi:10.1117/1.jbo.19.5.056010

Cited by 9 publications

(11 citation statements)

References 30 publications

(43 reference statements)

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“…Additionally, since SHGM arises from the thick-thin filament overlap in mature and developing sarcomeres [21] , its length was calculated as the mean width of the A-band-related peak (namely in our study as thick-thin filament interaction length; TTIL). The three distinctive sarcomere distances (SL, ABL and TTIL) were measured automatically with a custom algorithm based on an optimal fitting of a parametric model of the autocorrelation function of the SHGM intensity profile in sarcomere fibers, as previously reported [22] . Briefly, the local orientation of the sarcomere fibers was estimated to perform automatically the following tracking of all the fibers within an image.…”

Section: Methodsmentioning

confidence: 99%

Permanent Cardiac Sarcomere Changes in a Rabbit Model of Intrauterine Growth Restriction

et al. 2014

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BackgroundIntrauterine growth restriction (IUGR) induces fetal cardiac remodelling and dysfunction, which persists postnatally and may explain the link between low birth weight and increased cardiovascular mortality in adulthood. However, the cellular and molecular bases for these changes are still not well understood. We tested the hypothesis that IUGR is associated with structural and functional gene expression changes in the fetal sarcomere cytoarchitecture, which remain present in adulthood.Methods and ResultsIUGR was induced in New Zealand pregnant rabbits by selective ligation of the utero-placental vessels. Fetal echocardiography demonstrated more globular hearts and signs of cardiac dysfunction in IUGR. Second harmonic generation microscopy (SHGM) showed shorter sarcomere length and shorter A-band and thick-thin filament interaction lengths, that were already present in utero and persisted at 70 postnatal days (adulthood). Sarcomeric M-band (GO: 0031430) functional term was over-represented in IUGR fetal hearts.ConclusionThe results suggest that IUGR induces cardiac dysfunction and permanent changes on the sarcomere.

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Section: Methodsmentioning

confidence: 99%

Permanent Cardiac Sarcomere Changes in a Rabbit Model of Intrauterine Growth Restriction

et al. 2014

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“…However the mechanism underlying 2f sarcomeric SHG-IPs is still not completely elucidated. Several mechanisms have been proposed to explain the ultrastructural origin of this 2f sarcomeric SHG-IP encompassing centrosymmetry of antiparallel myosin tails arrangement at the M-band in normal cardiac muscles (Boulesteix et al, 2004;Garcia-Canadilla et al, 2014;Plotnikov et al, 2006), disease dependent myofibrillar deformation or change of myosin orientation (Friedrich et al, 2010), proteolysis induced intra-sarcomeric misalignment of myosin thick filaments (Rouede et al, 2011) and myofibrillar misalignment (Rouede et al, 2013a). Difficulties in correlating SHG and electron microscopy (EM) images represent the major technological limitation.…”

Section: Introductionmentioning

confidence: 99%

Structural origin of the drastic modification of second harmonic generation intensity pattern occurring in tail muscles of climax stages xenopus tadpoles

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Coumailleau

Rouède

et al. 2015

Journal of Structural Biology

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Second harmonic generation (SHG) microscopy is a powerful tool for studying submicron architecture of muscles tissues. Using this technique, we show that the canonical single frequency sarcomeric SHG intensity pattern (SHG-IP) of premetamorphic xenopus tadpole tail muscles is converted to double frequency (2f) sarcomeric SHG-IP in metamorphic climax stages due to massive physiological muscle proteolysis. This conversion was found to rise from 7% in premetamorphic muscles to about 97% in fragmented muscular apoptotic bodies. Moreover a 66% conversion was also found in non-fragmented metamorphic tail muscles. Also, a strong correlation between predominant 2f sarcomeric SHG-IPs and myofibrillar misalignment is established with electron microscopy. Experimental and theoretical results demonstrate the higher sensitivity and the supra resolution power of SHG microscopy over TPEF to reveal 3D myofibrillar misalignment. From this study, we suggest that 2f sarcomeric SHG-IP could be used as signature of triad defect and disruption of excitation-contraction coupling. As the mechanism of muscle proteolysis is similar to that found in mdx mouse muscles, we further suggest that xenopus tadpole tail resorption at climax stages could be used as an alternative or complementary model of Duchene muscular dystrophy.

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“…The first approach relies on a phenomenological profile definition such as a double Gaussian peak. 16,18 This is useful for analyzing double peaked intensity profiles observed in cardiac muscle tissue, but apart from the sarcomere length, the resulting parameter values have no direct relation to the biological structural properties of sarcomeres. The second approach is developed by Rouède et al 9 and relies on a more rigorous model based on the molecular organization of sarcomeres.…”

Section: Introductionmentioning

confidence: 99%

“…14 Various studies have recently emerged, suggesting SHG microscopy to be a valuable label-free tool to study muscular disorder. 13,15,16 However, to fully understand the effect of muscle degradation on the SHG signal, detailed knowledge of sarcomere structures and their relation to the second harmonic signal generation is necessary.…”

Section: Introductionmentioning

confidence: 99%

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On the interpretation of second harmonic generation intensity profiles of striated muscle

et al. 2015

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Abstract. Recently, a supramolecular model was developed for predicting striated skeletal muscle intensity profiles obtained by label-free second harmonic generation (SHG) microscopy. This model allows for a quantitative determination of the length of the thick filament antiparallel range or M-band (M), and results in M ¼ 0.12 μm for single-band intensity profiles when fixing the A-band length (A) to A ¼ 1.6 μm, a value originating from electron microscopy (EM) observations. Using simulations and experimental data sets, we showed that the objective numerical aperture (NA) and the refractive index (RI) mismatch (Δn ¼ n 2ω − n ω ) between the illumination wave (ω) and the second harmonic wave (2ω) severely affect the simulated sarcomere intensity profiles. Therefore, our recovered filament lengths did not match with those observed by EM. For an RI mismatch of Δn ¼ 0.02 and a moderate illumination NA of 0.8, analysis of single-band SHG intensity profiles with freely adjustable A-and M-band sizes yielded A ¼ 1.40 AE 0.04 μm and M ¼ 0.07 AE 0.05 μm for skeletal muscle. These lower than expected values were rationalized in terms of the myosin density distribution along the myosin thick filament axis. Our data provided new and practical insights for the application of the supramolecular model to study SHG intensity profiles in striated muscle.

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Automated cardiac sarcomere analysis from second harmonic generation images

Cited by 9 publications

References 30 publications

Permanent Cardiac Sarcomere Changes in a Rabbit Model of Intrauterine Growth Restriction

Permanent Cardiac Sarcomere Changes in a Rabbit Model of Intrauterine Growth Restriction

Structural origin of the drastic modification of second harmonic generation intensity pattern occurring in tail muscles of climax stages xenopus tadpoles

On the interpretation of second harmonic generation intensity profiles of striated muscle

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