Volume measurement variability in three-dimensional high-frequency ultrasound images of murine liver metastases

Wirtzfeld, Lauren A.; Graham, Kevin C.; Groom, A. C.; Macdonald, Ian; Chambers, Ann F.; Fenster, Aaron; Lacefield, James C.

doi:10.1088/0031-9155/51/10/002

Cited by 21 publications

(6 citation statements)

References 23 publications

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“…The advantages and limitations of these modalities, including positron emission tomography, single-photon emission computed tomography, computed tomography, magnetic resonance (MR), ultrasound, and bioluminescent and fluorescent optical imaging, are well documented (9)(10)(11)(12)(13)(14). To date, the majority of studies focusing specifically on solitary metastatic cells have relied on fluorescent optical imaging due primarily to the high-resolution capabilities of this modality.…”

Section: Introductionmentioning

confidence: 99%

Three-Dimensional Imaging and Quantification of Both Solitary Cells and Metastases in Whole Mouse Liver by Magnetic Resonance Imaging

et al. 2009

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The metastatic cell population, ranging from solitary cells to actively growing metastases, is heterogeneous and unlikely to respond uniformly to treatment. However, quantification of the entire experimental metastatic cell population in whole organs is complicated by requirements of an imaging modality with the large field of view and high spatial resolution necessary to detect both single cells and metastases in the same organ. Thus, it is difficult to assess differential responses of these distinct metastatic populations to therapy. Here, we develop a magnetic resonance imaging (MRI) technique capable of quantifying the full population of metastatic cells in a secondary organ. B16F1 mouse melanoma cells were labeled with micron-sized iron oxide particles (MPIO) and injected into mouse liver via the mesenteric vein. Livers were removed immediately or at day 9 or 11, following doxorubicin or vehicle control treatment, and imaged using a 3T clinical magnetic resonance scanner and custom-built gradient coil. Both metastases (>200 μm) and MPIO-labeled single cells were detected and quantified from MR images as areas of hyperintensity or hypointensity (signal voids), respectively. We found that 1 mg/kg doxorubicin treatment inhibited metastasis growth (n = 11 per group; P = 0.02, t test) but did not decrease the solitary metastatic cell population in the same livers (P > 0.05). Thus, the technique presented here is capable of quickly quantifying the majority of the metastatic cell population, including both growing metastases and solitary cells, in whole liver by MRI and can identify differential responses of growing metastases and solitary cells to therapy. [Cancer Res 2009;69(21):8326-31]

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Section: Introductionmentioning

confidence: 99%

Three-Dimensional Imaging and Quantification of Both Solitary Cells and Metastases in Whole Mouse Liver by Magnetic Resonance Imaging

et al. 2009

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“…The same trend has been reported in clinical imaging studies because repeated measurements by the same person are more likely to agree than measurements by different individuals. 16,17 Two-dimensional ultrasonographic volume measurements revealed several serious drawbacks based on the use of ellipsoid approximations of ovaries that do not always have regular geometric shapes. The choice of which of the 3 chords is to be used to measure the height, width, and length in a given set of images is not clear-cut and is largely dependent on observer preference, leading to high intraobserver variability in volume estimates.…”

Section: Discussionmentioning

confidence: 99%

Ovarian Volume Measurements in Mice With High-Resolution Ultrasonography

Lyshchik¹,

Hobbs²,

Fleischer³

et al. 2007

Journal of Ultrasound in Medicine

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Objective. The aim of our study was to evaluate the intraobserver and interobserver variability of ovarian volume measurements in mice with high-resolution 2-dimensional ultrasonography (2DUS) and 3-dimensional ultrasonography (3DUS). Methods. Ovaries of 10 nude mice were visualized with a small-animal ultrasound scanner and a 40-MHz probe. For each ovary, volume was measured 3 times by 2 independent readers using both 2DUS and 3DUS methods. The 2DUS method used a biplane ellipsoid model. The 3DUS method estimated the volume by integrating 10 to 12 parallel image planes of the ovary after semiautomated outlining of the boundaries. For each type of measurement, intraobserver and interobserver standard error of measurement (SEM) values and minimal detectable volume changes were calculated by analysis of variance. Results. Two-dimensional ultrasonography showed much poorer reproducibility, with higher absolute intraobserver and interobserver SEM values (0.50 and 0.61 mm 3 , respectively) than 3DUS (0.20 and 0.35 mm 3 ; P < .01). Relative intraobserver and interobserver SEM values were also much higher for 2DUS (12.20% and 14.88%) than for 3DUS (5.12% and 8.97%; P < .01). The minimal volume changes that could be detected with a 95% confidence level in successive measurements by the same (or different) observers were 33.90% (41.22%) for 2DUS and 14.10% (24.87%) for 3DUS. Conclusions. High-resolution 3DUS can provide a reliable tool for noninvasive, longitudinal ovarian volume measurements in mice. Key words: high-resolution ultrasonography; ovary; small-animal imaging.Received March 22, 2007, 1 Ovarian cancer is rarely diagnosed early, and reliable molecular or clinical markers to identify early changes have not been established. Moreover, prevention strategies that would inhibit early progression of this fatal disease are currently not available.Small-animal models of ovarian cancer have been used extensively in preclinical studies. Historically, most small-animal ovarian cancer research has relied on subcutaneous tumor models. These models allow for external measurements of tumor diameter using calipers to

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“…This application in experimental medicine can be useful in the detection of xenograft tumors in mice and in longitudinal growth. A set of consecutive 2D image planes of the tumor are acquired then reconstructed into 3D views for tumor estimation analysis [17, 18]. …”

Section: Ubm Methodologymentioning

confidence: 99%

Ultrasound Biomicroscopy in Small Animal Research: Applications in Molecular and Preclinical Imaging

Greco

Mancini

Gargiulo

et al. 2012

Journal of Biomedicine and Biotechnology

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Ultrasound biomicroscopy (UBM) is a noninvasive multimodality technique that allows high-resolution imaging in mice. It is affordable, widely available, and portable. When it is coupled to Doppler ultrasound with color and power Doppler, it can be used to quantify blood flow and to image microcirculation as well as the response of tumor blood supply to cancer therapy. Target contrast ultrasound combines ultrasound with novel molecular targeted contrast agent to assess biological processes at molecular level. UBM is useful to investigate the growth and differentiation of tumors as well as to detect early molecular expression of cancer-related biomarkers in vivo and to monitor the effects of cancer therapies. It can be also used to visualize the embryological development of mice in uterus or to examine their cardiovascular development. The availability of real-time imaging of mice anatomy allows performing aspiration procedures under ultrasound guidance as well as the microinjection of cells, viruses, or other agents into precise locations. This paper will describe some basic principles of high-resolution imaging equipment, and the most important applications in molecular and preclinical imaging in small animal research.

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Volume measurement variability in three-dimensional high-frequency ultrasound images of murine liver metastases

Cited by 21 publications

References 23 publications

Three-Dimensional Imaging and Quantification of Both Solitary Cells and Metastases in Whole Mouse Liver by Magnetic Resonance Imaging

Three-Dimensional Imaging and Quantification of Both Solitary Cells and Metastases in Whole Mouse Liver by Magnetic Resonance Imaging

Ovarian Volume Measurements in Mice With High-Resolution Ultrasonography

Ultrasound Biomicroscopy in Small Animal Research: Applications in Molecular and Preclinical Imaging

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