Fast Measurement of Sarcomere Length and Cell Orientation in Langendorff-Perfused Hearts Using Remote Focusing Microscopy

Botcherby, Edward; Corbett, Alexander D.; Burton, Rebecca A.B.; Smith, Christopher W.; Bollensdorff, Christian; Booth, Martin J.; Kohl, Peter; Wilson, Tony; Bub, Gil

doi:10.1161/circresaha.113.301704

Cited by 31 publications

(33 citation statements)

References 58 publications

(65 reference statements)

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“…2D) and endocardial to epicardial regional differences (11,28,30). The mean L s values determined for subepicardial cardiomyocytes in our preparation at 0 mmHg (young, 2.01 m; and aged, 2.02 m) fit well within the range (1.93 to 2.09 m) determined in unpressurized intact rat hearts (5,6) or fixed hearts maintained at 0 mmHg filling pressure (11,28,30). Upon left ventricular filling, the pressure versus L s relationship of hearts from young mice studied here (0 -40 mmHg L s range, 2.01 to 2.36 m) was also similar to that reported in classic measurements of dog hearts fixed ex vivo (0 -30 mmHg L s range, 1.93 to 2.33 m) (30) and from reconstructions of L s dynamics in vivo at physiological filling pressures (28).…”

Section: Comparison With Previous L S Measurements In the Heartsupporting

confidence: 78%

“…Angle of the longitudinal cell plane relative to the imaging plane, particularly with respect to rotation around the middle (width) axis of the cell, affects apparent L s as described in detail by Bub et al (6) and Botcherby et al (5). To determine this angular component, we performed optical sectioning (z sectioning) of subepicardial cardiomyocytes over a distance of 20 -25 m (section thickness of 1 or 2 m) to determine the number of optical sections separating longitudinal edges of cardiomyocytes.…”

Section: Dye Loading and Two-photon Imaging Of Perfused Heart Preparamentioning

confidence: 99%

“…For example, during submaximal Ca 2ϩ activation of isolated cardiomyocytes (7,9,13) or trabecular/papillary muscle preparations (17,19,32), contractile force can increase severalfold through the range in L s from ϳ1.70 to ϳ2.20 m. While force production as a function of L s has been well defined in isolated cardiac muscle preparations, there is a paucity of information concerned with how left ventricular filling pressure alters L s of cardiomyocytes in the intact living heart. Fluorescent labeling of the t-tubule network gives accurate indication of z-line spacing and therefore L s in cardiomyocytes of the rat heart (5,6). However, these latter studies examined L s in the absence of ventricular filling pressure.…”

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confidence: 99%

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Attenuated sarcomere lengthening of the aged murine left ventricle observed using two-photon fluorescence microscopy

Nance

Whitfield

Zhu

et al. 2015

American Journal of Physiology-Heart and Circulatory Physiology

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The Frank-Starling mechanism, whereby increased diastolic filling leads to increased cardiac output, depends on increasing the sarcomere length (Ls) of cardiomyocytes. Ventricular stiffness increases with advancing age, yet it remains unclear how such changes in compliance impact sarcomere dynamics in the intact heart. We developed an isolated murine heart preparation to monitor Ls as a function of left ventricular pressure and tested the hypothesis that sarcomere lengthening in response to ventricular filling is impaired with advanced age. Mouse hearts isolated from young (3-6 mo) and aged (24-28 mo) C57BL/6 mice were perfused via the aorta under Ca(2+)-free conditions with the left ventricle cannulated to control filling pressure. Two-photon imaging of 4-{2-[6-(dioctylamino)-2-naphthalenyl]ethenyl}1-(3-sulfopropyl)-pyridinium fluorescence was used to monitor t-tubule striations and obtain passive Ls between pressures of 0 and 40 mmHg. Ls values (in μm, aged vs. young, respectively) were 2.02 ± 0.04 versus 2.01 ± 0.02 at 0 mmHg, 2.13 ± 0.04 versus 2.23 ± 0.02 at 5 mmHg, 2.21 ± 0.03 versus 2.27 ± 0.03 at 10 mmHg, and 2.28 ± 0.02 versus 2.36 ± 0.01 at 40 mmHg, indicative of impaired sarcomere lengthening in aged hearts. Atomic force microscopy nanoindentation revealed that intact cardiomyocytes enzymatically isolated from aged hearts had increased stiffness compared with those of young hearts (elastic modulus: aged, 41.9 ± 5.8 kPa vs. young, 18.6 ± 3.3 kPa; P = 0.006). Impaired sarcomere lengthening during left ventricular filling may contribute to cardiac dysfunction with advancing age by attenuating the Frank-Starling mechanism and reducing stroke volume.

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Section: Comparison With Previous L S Measurements In the Heartsupporting

confidence: 78%

Section: Dye Loading and Two-photon Imaging Of Perfused Heart Preparamentioning

confidence: 99%

mentioning

confidence: 99%

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Attenuated sarcomere lengthening of the aged murine left ventricle observed using two-photon fluorescence microscopy

Nance

Whitfield

Zhu

et al. 2015

American Journal of Physiology-Heart and Circulatory Physiology

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“…However, taking into consideration the careful analysis by the group of Bub [10, 11] combined with our SL analysis based on the Gaussian fitting, the overestimation is ~2% in the present study, because the length of in-focus images in the image plane (i.e., L min in [10, 11]) was longer than ~70 μ m (e.g., Figures 1(a) and 1(b) ). It can therefore be considered that the influence of the myocyte angle on SL is practically negligible in the present experimental setting.…”

Section: Discussionmentioning

confidence: 59%

Optimization of Fluorescent Labeling for In Vivo Nanoimaging of Sarcomeres in the Mouse Heart

Kobirumaki-Shimozawa

Togo

Oyama

et al. 2018

BioMed Research International

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The present study was conducted to systematically investigate the optimal viral titer as well as the volume of the adenovirus vector (ADV) that expresses α-actinin-AcGFP in the Z-disks of myocytes in the left ventricle (LV) of mice. An injection of 10 μL ADV at viral titers of 2 to 4 × 1011 viral particles per mL (VP/mL) into the LV epicardial surface consistently expressed α-actinin-AcGFP in myocytes in vivo, with the fraction of AcGFP-expressing myocytes at ~10%. Our analysis revealed that SL was ~1.90-2.15 μm upon heart arrest via deep anesthesia. Likewise, we developed a novel fluorescence labeling method of the T-tubular system by treating the LV surface with CellMask Orange (CellMask). We found that the T-tubular distance was ~2.10-2.25 μm, similar to SL, in the healthy heart in vivo. Therefore, the present high-precision visualization method for the Z-disks or the T-tubules is beneficial to unveiling the mechanisms of myocyte contraction in health and disease in vivo.

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“…Intravital confocal and two-photon microscopy have been used in combination with fluorescence molecular imaging probes in cancer research, immunology, and the neurosciences to reveal biological processes at the cellular level in living organisms (2). Application of intravital techniques for imaging the beating heart in rodent models has been significantly limited by motion from cardiac contraction and respiration, and most studies as a result have used noncontracting Langendorf heart preparations (3)(4)(5)(6)(7)(8)(9)(10) or transplanted heart models (11). These model systems do not allow investigation of cardiomyocyte biology in the native heart under physiologic conditions.…”

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confidence: 99%

Intravital imaging of cardiac function at the single-cell level

Aguirre

Vinegoni

Sebas

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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Knowledge of cardiomyocyte biology is limited by the lack of methods to interrogate single-cell physiology in vivo. Here we show that contracting myocytes can indeed be imaged with optical microscopy at high temporal and spatial resolution in the beating murine heart, allowing visualization of individual sarcomeres and measurement of the single cardiomyocyte contractile cycle. Collectively, this has been enabled by efficient tissue stabilization, a prospective real-time cardiac gating approach, an image processing algorithm for motion-artifact-free imaging throughout the cardiac cycle, and a fluorescent membrane staining protocol. Quantification of cardiomyocyte contractile function in vivo opens many possibilities for investigating myocardial disease and therapeutic intervention at the cellular level.intravital micoscopy | molecular imaging | cardiovascular imaging | fluorescence | pacing W ith knowledge of the molecular bases for cardiovascular diseases expanding rapidly, a considerable void exists in our ability to phenotype heart function at the subcellular scale in vivo and in real time. Understanding how the fundamental unit of myocardial function, the cardiomyocyte, responds, adapts, and ultimately fails in response to stress, both individually and in a network of cells contributing to whole-organ function, is central to unraveling mechanisms of disease and designing novel therapies aimed at molecular pathways. The ability to measure single cardiomyocyte contractile function in vivo in the native environment is not possible using existing techniques.Optical microscopy has potential to assess cardiomyocyte structure and function in rodent models (1). Intravital confocal and two-photon microscopy have been used in combination with fluorescence molecular imaging probes in cancer research, immunology, and the neurosciences to reveal biological processes at the cellular level in living organisms (2). Application of intravital techniques for imaging the beating heart in rodent models has been significantly limited by motion from cardiac contraction and respiration, and most studies as a result have used noncontracting Langendorf heart preparations (3-10) or transplanted heart models (11). These model systems do not allow investigation of cardiomyocyte biology in the native heart under physiologic conditions. A few studies have achieved intravital imaging in orthotopic hearts at relatively modest spatial and temporal resolutions that prevent visualization of subcellular structures. Essential to these techniques are methods of macrostabilization such as affixing the heart with sutures (12), compressing the heart with a coverslip (11, 13), bonding the heart with a mechanical stabilizer (14), or suction-based devices (15,16). Although tissue stabilization methods alone can facilitate very-low-resolution cardiac imaging (e.g., microvasculature, cellular recruitment, and flow), they do not achieve the necessary temporal or spatial resolution for subcellular imaging of cardiomyocytes throughout the cardiac cycle. To f...

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Fast Measurement of Sarcomere Length and Cell Orientation in Langendorff-Perfused Hearts Using Remote Focusing Microscopy

Cited by 31 publications

References 58 publications

Attenuated sarcomere lengthening of the aged murine left ventricle observed using two-photon fluorescence microscopy

Attenuated sarcomere lengthening of the aged murine left ventricle observed using two-photon fluorescence microscopy

Optimization of Fluorescent Labeling for In Vivo Nanoimaging of Sarcomeres in the Mouse Heart

Intravital imaging of cardiac function at the single-cell level

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