Abstract
Muscle atrophy is a widespread ill condition occurring in many diseases, which can reduce quality of life and increase morbidity and mortality. We developed a new method using non-invasive ultrasonography to measure soleus and gastrocnemius lateralis muscle atrophy in the hindlimb-unloaded rat, a well-accepted model of muscle disuse. Soleus and gastrocnemius volumes were calculated using the conventional truncated-cone method and a newly-designed sinusoidal method. For Soleus muscle, the ultrasonographic volume determined in vivo with either method was linearly correlated to the volume determined ex-vivo from excised muscles as muscle weight-to-density ratio. For both soleus and gastrocnemius muscles, a strong linear correlation was obtained between the ultrasonographic volume and the muscle fiber cross-sectional area determined ex-vivo on muscle cryosections. Thus ultrasonography allowed the longitudinal in vivo evaluation of muscle atrophy progression during hindlimb unloading. This study validates ultrasonography as a powerful method for the evaluation of rodent muscle atrophy in vivo, which would prove useful in disease models and therapeutic trials.
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Introduction
Muscle atrophy is a widespread ill condition occurring during inactivity, aging and various diseases, including neuromuscular disorders, cancer, bacterial and viral infections, chronic lung and kidney diseases, diabetes and drug side effects1,2. The loss of muscle mass and function can reduce quality of life and increase morbidity and mortality. While exercise is today the only recognized counteracting measure to slow atrophy, a number of studies in the last decade have shed light on the underlying molecular mechanisms, paving the way for drug development. This later will require preclinical models and associated powerful techniques to evaluate trial outcomes. To date the measure of muscle atrophy in animal disease models usually requires animal sacrifice in order to weigh excised muscles and perform histological and biochemical studies. This approach is invasive and expensive involving the use of a large number of animals to obtain significant results. Therefore realizing a new, non invasive method allowing longitudinal in vivo evaluation of muscle atrophy would become an invaluable tool.
The ultrasonography is a non invasive diagnostic imaging technique based on the application of ultrasounds, which is widely used for various medical applications, including the quantification of structural and functional changes in skeletal muscles3,4. In the recent years, the technique has been adapted to the preclinical setting, owing to the development of equipment able to work at high frequencies, from 40 to 100 MHz and therefore suitable for high-resolution ultrasound evaluations on small animals such as rodents5. While ultrasonography has been mostly used for tumor and cardiac investigations6,7,8,9, there are currently only a few reports relative to its use for the evaluation of skeletal muscle structural and functional parameters in rodents. The aim of this study was to develop a non-invasive method to evaluate in vivo the volume variation of hindlimb muscle of rats, as a measure of skeletal muscle atrophy, using ultrasonography. To achieve this goal, we performed a longitudinal ultrasonographic study of rat soleus (Sol) and gastrocnemius lateralis (Gas) muscle volume variation during a 14-days hindlimb-unloading (HU) period, which is a widely acknowledged model of disuse-induced muscle atrophy10,11.
Results and Discussion
Ultrasound B-Mode acquisitions of Sol and Gas muscle images were performed at day 0 (D0), 7 (D7) and 14 (D14) in control (CTRL) and hindlimb unloaded (HU) adult rats. The anaesthetized rat was placed in the ventral decubitus position and the 40-MHz probe was fixed parallel to the hindlimb (Supplementary Fig. 1). In this condition, it was possible to visualize the whole length of the Sol and Gas muscles tendon-to-tendon by shifting the probe along the longitudinal axis. For image analysis, the Sol and Gas muscles were virtually divided in distal and proximal parts with approximately similar lengths (Fig. 1a,b). The Sol and Gas volumes were calculated by using both the conventional truncated-cone method, which is currently used for the assessment of human muscle volume12 and a newly-designed sinusoidal method (see methods). The first method consists in summing the calculated volumes of designed truncated cones covering the whole muscle image (Fig. 2). The new sinusoidal method considers the fusiform profile of the spindle-shaped Sol and Gas muscles resembling a sinusoidal function and the Sol and Gas volumes are approximated by the rotation around the tendon-to-tendon axis of a sine function (Figs 3, 4, 5).
The results showed that, independently on the calculation method, no significant changes of Sol and Gas muscle volumes occur in CTRL rats between D0, D7 and D14 (Fig. 6a,b). Within the HU group, a significant reduction of Sol and Gas muscle volumes was observed at D7 and D14 with respect to D0, both with the truncated-cone and sinusoidal methods (at least p < 0.01 with paired Student’s t-test) (Fig. 6a,b). Note that no significant difference was found between the right and left limbs of HU rats (not shown) and muscle volumes of both limbs were averaged to obtain a single value for each animal. Regarding Gas muscle, the percentage reduction of Sol muscle volume at D7 and D14 was −12.4 ± 2.2% and −21.9 ± 1.7%, respectively, with the truncated cone method and −12.7 ± 1.3% and −20.8 ± 1.2% with the sinusoidal method. Consistently, the Gas muscle volume of HU rats (n = 5) was significantly reduced with respect to that of CTRL animals (n = 3) at D7 (−16.0 ± 2.2% and −14.4 ± 2.9%, truncated-cone and sinusoidal methods, p < 0.005 with unpaired Student’s t-test) and D14 (−28.4 ± 2.2% and −26.4 ± 2.0%, p < 0.0002) (Fig. 6a). Compared to D0, the percentage reduction of Sol muscle volume at D7 and D14 was −20.1 ± 1.9% and −27.9 ± 3.5%, respectively, with the truncated cone method and −16.9 ± 2.6% and −25.6 ± 4.6% with the sinusoidal method. With respect to that of CTRL animals (n = 9), the Sol muscle volume of HU rats (n = 11) was significantly reduced at D7 (−27.9 ± 3.6% and −23.8 ± 2.9%, truncated-cone and sinusoidal methods, p < 0.0001 with unpaired Student’s t-test) and D14 (−38.6 ± 3.8% and −37.1 ± 4.2%, p < 0.0002) (Fig. 6b). These values are in line with the percentage reductions observed in previous studies, in which Sol or Gas muscle atrophy was evaluated ex-vivo as a reduction of muscle weight13,14,15,16,17,18,19.
At D14, a linear correlation (y = ax + b) between the ultrasonographic volumes and the weight-to-density ratio of Sol muscles excised from the same animal was observed, showing a coefficient of determination r2 of 0.73 and 0.83 with the truncated-cone or the sinusoidal methods, respectively (Fig. 6c). Despite the fact that we can quantify the Sol muscle volume variations, we cannot directly measure the actual absolute Sol muscle volume using ultrasonography. Such a difference is at least partially due the actual ellipse-like cross section of the Sol muscle, which is underestimated by the circular cross section of the truncated cones or the sinusoidal spindle. Nevertheless, the linear correlation provides us with the possibility to satisfactorily approximate the actual soleus volume from that measured with ultrasonographic technique (Fig. 6c). No such satisfactory correlation was obtained for Gas muscle (r2 = ∼0.5, not shown), due to technical limitation in the excision of Gas muscles resulting in highly variable Gas muscle weights.
One of the most accurate method to evaluate muscle atrophy ex-vivo consists in the measure of muscle fiber cross-sectional area in muscle cryosections. We performed this analysis on laminin-stained cryosections of Sol and Gas muscles excised from 3 CTRL and 5 HU rats at D14 (Fig. 7a,b). In Sol muscle, the CSA was reduced from 3210 ± 283 in CTRL to 2026 ± 46 μm2 in HU (−36.9 ± 5.3%, P < 0.002 with unpaired Student’s t-test). In Gas muscle, the CSA reduction was from 2856 ± 158 in CTRL to 1892 ± 57 μm2 in HU (−33.8 ± 3.2%, P < 0.002 with unpaired Student’s t-test). These averaged values are closed to those of reduction of ultrasonographic volumes reported above (∼38% for Sol and ∼28% for Gas). Importantly, there was a strong linear correlation (r2 > 0.89) between the fiber CSA and the ultrasonographic volume of Sol or Gas muscles determined in the same animals, with either the truncated cone method (Fig. 7c) or the sinusoidal method (Fig. 7d).
This study shows, for the first time, the evaluation of skeletal muscle volume in rodents by using ultrasonography. We were able to monitor over time the Sol and Gas muscle atrophy in the same animals. Such a non-invasive technique represents a breakthrough in skeletal muscle research as it allows longitudinal in vivo studies, which would be especially helpful to measure muscle atrophy progression in rodent models of diseases (neuromuscular diseases, but also aging, cancer, virus infection, drug side effects, etc…) and to perform preclinical trials of candidate drugs and regenerative therapies. Although the ultrasound technique is reputedly limited to superficial muscles, thanks to the high frequency probe, we were able to measure the volume variation of the deep soleus and the more superficial gastrocnemius lateralis. Interestingly, the ultrasonography accessibility to both a slow-twitch, oxidative muscle (Soleus) and a fast-twitch, glycolytic muscle (Gastrocnemius), may be particularly relevant to study muscle phenotype-dependent atrophic processes. Besides its relative low cost, one of the advantage of the ultrasound technique with respect to other in-vivo imaging techniques, such as computerized tomography (CT) single photon emission computed tomography (SPECT) and positron emission tomography (PET), is the lack of ionizing radiations, which may be harmful especially during repetitive exams in longitudinal studies. Although it is noteworthy that magnetic resonance imaging (MRI) can provide reliable evaluation of skeletal muscle volumes, the MRI scanners are very expensive, may be affected by little movements of animals and may require the use of contrast agents. Thus ultrasound sonography may appear as a very useful and accessible method to perform preclinical studies. Similarly, recent studies suggest that muscle ultrasonography may provide physiatrists with a practical and accurate tool for diagnosis of muscle atrophy in humans20,21.
We designed a novel method to evaluate the muscle volume. The novel sinusoidal method showed at least the same accurateness than the conventional truncated-cone method, as demonstrated by the linear correlation coefficients. In addition, the sinusoidal method allowed the final volume calculation by measuring only four parameters (A1, A2, d1 and d2), compared to fifty parameters for the truncated-cone method (Figs 2a, 3a and 5a). This aspect would imply an easier and faster analysis possibly with a lower margin of error.
In conclusion, our study provides a new method for the in vivo determination of rat muscle volume validating ultrasonography as a powerful approach for the evaluation of rat skeletal muscle atrophy. As already happened for cardiac physiology, ultrasound imaging has the potentiality to become a gold standard for the acquisition and measurement of skeletal muscle volume. Additional improvements may be obtained by extending this method to other skeletal muscles. The non-invasive ultrasound technique allows longitudinal studies in vivo, which may prove very useful for preclinical evaluation of skeletal muscle structural parameters in physiopathological conditions and after therapeutic intervention. Furthermore, the ultrasonographic volume evaluation could be a starting point for the non invasive assessment of functional parameters, such as the physiological cross sectional area and the power potential3. Last but not least, such technique would allow to decrease the number of animals needed to obtain statistically significant results.
Materials and Methods
HU experiments
The hindlimb unloading (HU) experiments were performed in accordance with the Italian Guidelines for the use of laboratory animals (d.Lgs 2014 n. 26), which conforms with the European Union Directive for the protection of experimental animals (2011/63/EU) and received approval from the Italian Ministero della Salute (D.M. n.133/2000-B). Adult male Wistar rats, weighting 295–360 g, (Charles River Lab., Calco, Italy) were randomly distributed into two groups: control (CTRL) and hindlimb-unloaded groups (HU). Two series of experiments were performed. The first experiment, including 6 CTRL and 6 HU rats, was performed to compare ultrasonographic volume to muscle weight-to-density ratio of the soleus muscle only. In the second experiment, including 3 CTRL and 5 HU rats, ultrasonographic volume, muscle weight-to-density ratio and muscle fiber cross sectional area (CSA) were compared in both soleus and gastrocnemius muscles. Because the two experiments showed very similar results for Soleus muscle, data were pooled together. The HU rats were suspended individually in special cages for 14 days10. The rats were suspended by means of a shoelace linked at one extremity to the base of the tail by sticking plaster and at the other extremity to a trolley that can move on horizontal rails at the top of the cage14,15,16,17,22. The length of the lace was adjusted to allow the animals to move freely on their forelimbs, while the body was inclined at 30–40° from the horizontal plane. Control and suspended animals had food and water ad libitum. Animals were inspected each day for fine-tuning of suspension and control of animal health.
At day 0, 7 and 14 (D0, D7 and D14, respectively) the rats were weighted and ultrasound image acquisitions of the Sol and Gas muscles were performed. At D14, after ultrasonographic image acquisition, the rats were sacrificed by using an overdose of intraperitoneal injection of urethane and the Sol and Gas muscles from both legs were quickly removed and weighted. The Sol and Gas muscle volumes were calculated by dividing weight (g) by muscle density (0.00106 g/mm3), assuming that muscle density did not change between CTRL and HU rats23.
Histological analysis
Gastrocnemius lateralis and soleus muscles, covered with tissue-tek O.C.T. (Bio-Optica), were frozen in isopentane cooled in liquid nitrogen in a slightly stretched position and stored at −80 °C. Serial cross sections (8-μm thick) were cut in a cryostat microtome set a −20 °C (HM525 NX, Thermo Scientific). To measure the cross-sectional area (CSA) of individual fibers, muscle sections were stained for laminin, a major component of the basal lamina, as previously described24. The sections were incubated with primary antibody against rabbit laminin (SIGMA Aldrich c.n. L9393) diluted 1:200 in PBS-gelatin for 1 h. After washing with PBS-gelatin, the sections were incubated with donkey anti rabbit IgG (Invitrogen c.n. A-21206) diluted 1:1000 in PBS-gelatin for 1 h, then washed with PBS-NaCl (300 mM). Sections were examined using Olympus CX41 microscope. Five digital photographs were taken of each muscle section and the CSA was measured as the internal laminin-unstained area by the ImageJ software (NIH, freeware imaging software). For each muscle sample, the number of counted fibers ranged between ∼350 and ∼900 fibers.
Ultrasonography
Ultrasonography was performed using an UBM system (Vevo 2100; VisualSonics, Toronto, ON, Canada) (Supplementary Fig. 1a). For image acquisition, the rats were anaesthetized with isofluorane at a concentration of 1.5–2% and placed in the ventral decubitus position (Supplementary Fig. 1b). The hind limbs were shaved to avoid interference in the image and positioned strictly parallel to the rat body, with foot forming an angle of 90° with the hind limb. Image acquisitions were performed operating at a frequency of 40 MHz for B-Mode acquisition of Sol and Gas muscle images. The B-Mode images were generated with a 14 × 14 mm view field and at a frame of 15 Hz. Lateral and axial resolutions were 80 and 40 μm, respectively. For longitudinal image acquisition of Sol and Gas muscles, the probe was fixed parallel to the hindlimb (Supplementary Fig. 1b). Because of the unfeasibility to acquire an ultrasound image of the whole muscles in their length, a thin strip (2 mm) of micropore tape (3M, Bracknell, UK) was used to mark a virtual transversal division of the Sol and Gas muscles in distal and proximal parts with approximately similar lengths (Fig. 1a,b). Eye lubricant was placed on each eye to prevent drying of the area and a small amount of ECG gel was placed on the platform copper leads to allow ECG and respiratory recording. A rectal probe was used to monitor the temperature of the animal during the imaging session. An ultrasound gel was added between the animal skin and the probe and a minimal pressure was applied to the muscle to minimize image distortion.
By the end of ultrasonography session, the rat was allowed to recover from anesthesia (usually 20 min) before to be re-suspended (D0 and D7) or immediately sacrificed by i.p. urethane overdose administration (D14).
Utrasonographic evaluation of Soleus and Gastrocnemius muscle volume
The ultrasonographic evaluation of Sol and Gas muscle volume was performed by using the conventional truncated-cone method12 and a novel sinusoidal method.
The truncated-cone method consists in the calculation of the volumes of contiguous truncated cones drawn in the distal and proximal parts of the muscle (Fig. 2a,b). Each truncated cone volume is calculated from the equation,
where r1 is the minor radius, r2 is the major radius, h is the height and π = 3.142 (Fig. 2c,d). The rat Sol and Gas muscles were subdivided in 8 contiguous truncated cones. The total volume of Sol and Gas muscles is calculated as the sum of all truncated cones volumes.
For the Sol muscle, the sinusoidal method was designed assuming that the muscle observed in the ultrasonographic window (sum of proximal and distal views) is spindle-shaped, with the fusiform profile resembling a sinusoidal function. The proximal and distal volumes can be approximated by the rotation around the tendon-to-tendon axis of a sine function, delimited by the measurements A1 and d1 or A2 and d2 (cyan lines showed in (Fig. 3a) and by a1 and a2 that are the sinusoidal arches (Fig. 3b).
Considering the proximal part, the volume is calculated considering the rotation around the hypotenuse hyp of an hypothetical right triangle with major cathetus d1 and minor cathetus (A1/2) (Fig. 3c). The hyp length can be calculated using the following formula:
It is possible to approximate the length of hyp to the length of d1, which is easily measured on the acoustic window. The approximation introduced an error of only some undreadth of millimeter. Indeed, the hyp value calculated from the mean value of d1 and A1 at D0 (10.86 ± 0.12 (n = 12) and 1.94 ± 0.04 (n = 12), respectively) was 10.90 mm. thus the relative error between hyp and d1 calculated using the following formula [((hyp − d1)/d1) · 100] was only 0.4%. The same considerations apply to the distal part (Fig. 3c). Thus the Sol muscle volume can been calculated from the sum of the proximal and distal volumes calculated by the rotation around d1 and d2 of a sine function (Fig. 4a,b). We measured the A1 and A2 values by considering the greater thickness of the muscle and we calculated the A value as
The sine function around the x axis with amplitude A and distances d1 and d2 returned the volume (Fig. 4c).
In order to apply the sine function, it is necessary to change the x variable (mm) in z variable (radians) using the following proportion:
Replacing this new variable in the sine function, we obtained the following equation
f(x) = A sin z = A sin [π x/(d1 + d2)] (Fig. 4d).
This equation has been used to calculate the proximal and distal volume of soleus muscle, considering the solid of rotation applying the Guldino’s formula:
Similarly, the volume of distal part of the muscle is obtained from:
By summing Vp and Vd, the whole Soleus muscle volume can be calculated as:
Finally, by using the Prosthaphaeresis formula, for which
we concluded that the volume generated by the sine function around the x axis with amplitude A and distances d1 and d2 is:
Since the gastrocnemius lateralis muscle is leaning on the soleus muscle, we assume that the lower profile of Gas follows a similar sinusoidal profile (Fig. 5a). Looking at the ultrasonographic window, also the upper profile of Gas muscle appears as a sinusoidal arc. The median line (d1), which is the line formed by all points equidistant from the arcs a1 and a3 for the proximal Gas (Fig. 5b) and the median line d2 equidistant from a2 and a4 arcs for the distal Gas, are symmetry lines between arcs a1, a3 and a2, a4. Above and below these symmetry lines, the profile of Gas muscle is sinusoidal. Therefore, d1 and d2 can be placed on an x axis to obtain a geometrical model of the muscle volume (Fig. 4a,b). The whole volume is achieved by coupling proximal and distal parts (Fig. 4c). As for the soleus, considering the solid of rotation and applying the Guldino’s formula we get final formula to calculate the whole Gas volume:
Statistical analysis
Each point of the volume time-course relationship represents the mean ± standard error from n rats. Because no significant difference was found between the two hind limbs of each rat with either calculation method, the single rat value was calculated as the mean of the ultrasonographic volume of left and right soleus muscles. Statistical analysis was performed by Student’s paired t test within the groups or Student’s unpaired t test between the groups. Differences were considered significant for p < 0.05 or less.
Additional Information
How to cite this article: Mele, A. et al. In vivo longitudinal study of rodent skeletal muscle atrophy using ultrasonography. Sci. Rep. 6, 20061; doi: 10.1038/srep20061 (2016).
References
Schiaffino, S., Dyar, K. A., Ciciliot, S., Blaauw, B. & Sandri, M. Mechanisms regulating skeletal msucle growth and atrophy. FEBS J. 280, 4294–4314 (2013).
Cohen, S., Nathan, J. A. & Goldberg, A. L. Muscle wasting in disease: molecular mechanisms and promising therapies. Nature Rev. Drug Discov. 14, 58–74 (2014).
Morse, C. I., Thom, J. M., Birch, K. M. & Narici, M. V. Changes in triceps surae muscle architecture with sarcopenia. Acta Physiol. Scand. 183, 291–298 (2005).
Mourtzakis, M. & Wischmeyer, P. Bedside ultrasound measurement of skeletal muscle. Curr. Opin. Clin. Nutr. Metab. Care 17, 389–395 (2014).
Coatney, R. W. Ultrasound imaging: principles and applications in rodent research. ILAR J. 42, 233–247 (2001).
Goessling, W., North, T. E. & Zon, L. I. Ultrasound biomicroscopy permits in vivo characterization of zebrafish liver tumors. Nat. Methods 4, 551–553 (2007).
Baumann, P. Q., Sobel, B. E., Tarikuz Zaman, A. K. & Schneider, D. J. Gender-dependent differences in echocardiographic characteristics of murine hearts. Echocardiography 25, 739–748 (2008).
Liu, J. & Rigel, D. F. Echocardiographic examination in rats and mice. Methods Mol. Biol. 573, 139–155 (2009).
Jin, Y., Tong, D., Shen, J., Yang, J. & Li, J. Establishment of experimental implantation tumor models of hepatocellular carcinoma in Wistar rats. Tumour Biol. 35, 9079–9083 (2014).
Morey-Holton, E., Globus, R. K., Kaplansky, A. & Durnova, G. The hindlimb unloading rat model: literature overview, technique update and comparison with space flight data. Adv Space Biol Med. 10, 7–40 (2005).
Baldwin, K. M., Haddad, F., Pandorf, C. E., Roy, R. R. & Edgerton, V. R. Alterations in muscle mass and contractile phenotype in response to unloading models: role of transcriptional/pretranslational mechanisms. Front. Physiol. 4, 284 (2013).
Tomlinson, D. J., Erskine, R. M., Winwood, K., Morse, C. I. & Onambélé, G. L. The impact of obesity on skeletal muscle architecture in untrained young vs. old women. J. Anat. 225, 675–684 (2014).
Desaphy, J. F. et al. Skeletal muscle disuse induces fibre type-dependent enhancement of Na + channel expression. Brain 124, 1100–1113 (2001).
Pierno, S. et al. Change of chloride ion channel conductance is an early event of slow-to-fast fibre type transition during unloading-induced muscle disuse. Brain 125, 1510–1521 (2002).
Desaphy, J.-F. et al. Recovery of the soleus muscle after short- and long-term disuse induced by hindlimb unloading: effects on the electrical properties and myosin heavy chain profile. Neurobiol. Dis. 18, 356–365 (2005).
Tricarico, D. et al. The KATP channel is a molecular sensor of atrophy in skeletal muscle. J. Physiol. 588, 773–784 (2010).
Desaphy, J.-F. et al. Antioxidant treatment of hindlimb-unloaded mouse counteracts fiber type transition but not atrophy of disused muscles. Pharmacol. Res. 61, 553–563 (2010).
Jackson, J. R., Ryan, M. J., Hao, Y. & Always, S. E. Mediation of endogenous antioxidant enzymes and apoptotic signaling by resveratrol following muscle disuse in the gastrocnemius of young and old rats. Am. J. Physiol. Regul. Integr. Comp. Physiol. 299, R1572–R1581 (2010).
Fujita, R. et al. Effects of molecular hydrogen saturated alkaline electrolyzed water on disuse muscle atrophy in gastrocnemius muscle. J. Physiol. Anthropol. 30, 195–201 (2011).
Abe, T. et al. Site-specific thigh muscle loss as an independent phenomenon for age-related muscle loss in middle-aged and older men and women. Age (Dordr) 36(3), 9634 (2014).
Minetto, M. A. et al. Ultrasound-based detection of low muscle mass for diagnosis of sarcopenia in older adults. PM R. Sep 30, 2015 pii: S1934–1482(15)01022-9. doi: 10.1016/j.pmrj.2015.09.014. [Epub ahead of print].
Tricarico, D., Mele, A. & Conte Camerino, D. Phenotype-dependent functional and pharmacological properties of BK channels in skeletal muscle: effects of microgravity. Neurobiol. Dis. 20, 296–302 (2005).
Urbanchek, M. G., Picken, E. B., Kalliainen, L. K. & Kuzon, W. M., Jr. Specific force deficit in skeletal muscles of old rats is partially explained by the existence of denervated muscle fibers. J. Gerontol. A Biol. Sci. Med. Sci. 56, B191–197 (2001).
Camerino, G. M. et al. Effects of pleiotrophin overexpression on mouse skeletal muscles in normal loading and in actual and simulated microgravity. Plos One 8(8), e72028 (2013).
Acknowledgements
This study was supported by the Italian Ministry of Education, Universities and Research (grant number PONa3_00395 “Biosciences & Health”) and the Italian Ministry of Health (grant number GR-2009-1580433).
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A.M., D.C.C. and J.-F.D. designed the study. A.M., A.F. and F.R. performed the HU and ultrasonography experiments and analyzed the data. F.R. designed the sinusoidal analysis method. G.M.C., M.D.B., E.C. and A.G. performed histological analysis. A.M., A.F. and F.R. wrote a draft of the manuscript. J.-F.D. and D.C.C. wrote the final version of the manuscript.
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Mele, A., Fonzino, A., Rana, F. et al. In vivo longitudinal study of rodent skeletal muscle atrophy using ultrasonography. Sci Rep 6, 20061 (2016). https://doi.org/10.1038/srep20061
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DOI: https://doi.org/10.1038/srep20061
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