Micro-ultrasound in Cancer Angiogenesis: Overview

Executive Summary
Background on Cancer Angiogenesis
Animal Research in Cancer Angiogenesis and Examples of Micro-Ultrasound 
Market Research and VisualSonics’ Value Proposition
References

Executive Summary

Tumor angiogenesis is currently one of the key focal points in biomedical research. It is based upon the hypothesis laid out by Judah Folkman in 1971 that neovasculature is needed to support the growth and metastasis of tumors, and thus anti-angiogenic treatment might be an effective way to cure cancer. Genentech’s anti-VEGF-A drug Avastin a great demonstration of this concept, generating more than $2.7 billion of sales in 2008.

However, cancer angiogenesis research in animal models has long been hindered by the lack of a fast, portable, high resolution, research and animal focused imaging system that can visualize 3D tumor volume, neoangiogenesis, and blood perfusion <i>in vivo</i>, in real-time and most importantly, non-invasively. Indeed, it took 33 years after Folkman’s hypothesis for the first anti-angiogenic treatment to be approved by the FDA. In order to ameliorate this problem, VisualSonics has introduced a revolutionary micro-ultrasound system that allows researchers to collect a plethora of important data over the lifespan of animals, thereby significantly reducing the number of animals needed. 3D tumor volume, tumor vascularity and tissue perfusion can be quickly quantified, while Vevo MicroMarker^® contrast agents allow the visualization of capillaries and also to track expression of endothelial cell markers such as VEGF.

Numerous satisfied cancer researchers using Vevo^® micro-ultrasound systems, from institutions such as Vanderbilt, Stanford and Toronto are publishing articles in leading journals such as Science, Clinical Cancer Research, PNAS and Cancer Research. This is a testament of the power and versatility of high resolution ultrasound.

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Background on Cancer Angiogenesis

The field of cancer angiogenesis was established by Folkman in his novel hypothesis published in 1971,¹ in which he suggested that tumor growth is angiogenesis dependant. If angiogenesis can be stopped or prevented from occurring, then tumors would no longer be able to proliferate and harm its host. Over the next few decades, new research findings have further advanced this field. For example, it’s been found that in situ carcinomas may exist for years without switching to the angiogenic phenotype. This neoangiogenesis event is governed, at least in part, by the balance of positive and negative angiogenic factors, such as VEGF, aFGF, bFGF, angiogenin, etc.²

Armed with this information, scientists began earnestly to look for the silver-bullet: anti-angiogenic compounds that have low toxicity, low drug resistance, and high efficacy.² However, it was 33 years later before the first anti-angiogenic therapy, bevacizumab, was approved by the FDA.³ Specifically, bevacizumab is a humanized antibody against vascular endothelial growth factor A (VEGF-A). Since then, other anti-angiogenic compounds have been approved around the world,⁵ but it has been clear that the survival benefits offered by these expensive therapies were modest at best.³ In order to further understand the mechanisms behind these drugs and to improve therapy, new theories have been postulated, including the theory of transient “tissue normalization” caused by these drugs.⁶

In today’s research, time is of the essence. To test these novel hypotheses and discover new drugs that will hopefully be on the market before three more decades, scientists need access to imaging modalities that grant them the possibility of visualizing tumor angiogenesis in vivo, non-invasively, and in real-time. Obviously, histology and dissection do not fill these criteria. MRI, PET and SPECT, while each having unique benefits, still suffer from problems such as radiation, high setup/maintenance costs and lack of vasculature-confined contrast agents. This is where high frequency ultra-sound comes in.

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Animal Research in Cancer Angiogenesis and Examples of Micro-Ultrasound

Micro-ultrasound using high frequency probes and intravenous contrast agents has been regarded as an attractive technique for accessing angiogenic activity and monitoring anti-angiogenic therapy.⁷ Most research in this area is done using mice, because of their wide availability, variety of strains, and ease of handling. Micro-ultrasound is especially suitable to study mice as they are the perfect size to take advantage of the maximum resolution Vevo systems offer.

For example, Olive et al. recently reported their findings in Science of using the Vevo high resolution system to image normal and diseased tissue in a mouse model of pancreatic cancer.⁸ In addition to measuring 3D tumor volume twice weekly, the researchers were able to make use of Vevo MicroMarker microbubbles to visualize tumor perfusion. With this tool, they were able to determine that KPC (Kip1 ubiquitylation-promoting complex) tumors were poorly perfused within the tumor parenchyma, despite being surrounded by well-perfused tissue.⁸ The group also used micro-ultrasound to detect changes in the tumor with injection of gemcitabine, which caused transient response in the tumor correlating to high levels of apoptosis.⁸

Palmowski et al. recently published in Cancer Research their findings of using high-frequency volumetric Power Doppler ultrasound to capture flow-dependant signals and assess antiangiogenic effects in a murine A431 model.⁹ The researchers used the Vevo 770 system to visualize the effects of administration of SU11248 on tumor volumes and vascularity over a period of 9 days.⁹ In addition, the researchers made use of a novel technique: destruction of microbubbles by high-mechanical index ultrasound sonoporation with the Vevo system, to allow for a superior visualization of early antiangiogenic effects.

Many other researchers in recent years have also been using Vevo systems as an easily accessible, applicable, fast, and superior way to image tumor volume and angiogenesis. For a complete list of publications, please refer to document titled Bibliography of Recent Cancer Research Papers featuring Vevo Systems.

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Market Research and VisualSonics' Value Proposition

Cancer research and angiogenesis visualization has traditionally been associated with imaging modalities such as MRI, CT, PET and SPECT. However, despite their various strengths, many of these systems suffer from significant drawbacks, including significant costs, in addition with complicated operating needs such as radioisotopes. Furthermore, none of the above imaging modalities is real-time per se, compared with micro-ultrasound which can capture images at up to 300 frames per second to study blood flow and perfusion. With Vevo systems, researchers now have access to a tool to visualize small animals in real time and in vivo. In fact, it has been demonstrated by Loveless et al. that micro-ultrasound produces images eclipsing MRI resolution, and that the two imaging systems can be combined to validate each other’s results.¹⁰

Below is a summary of the unique value proposition VisualSonics delivers to researchers with the Vevo micro-ultrasound systems:

Non-invasive, in vivo, real-time imaging for processes that happen over a period of time, such as angiogenesis and tumor volume changes.

1. Screening modality for early tumor detection (50 µm or larger in diameter).
2. Quantification of tumor volumes in 2D and 3D.
3. Monitoring blood flow velocity and tumor perfusion.
4. Observation of capillary formation and flow in neoangiogenesis.
5. Targeted biomarker molecular imaging with antibody-bound contrast agents. (VEGFR, integrins, etc.)
6. Guidance of micro-injections of stem cells, drugs, interstitial pressure probes etc into tumors or vasculature.
7. Detection and quantification of cardiotoxicity in response to cancer therapy.
8. Dedicated animal platform to monitor ECG, heart rate, body temperature and respiration rates.

For a full list of cancer applications with the Vevo system, together with examples from literature, please consult White Paper: High Resolution Micro-Ultrasound for Small Animal Cancer Imaging.

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References

1. Folkman J. Tumor angiogenesis: therapeutic implications. N Engl J Med 1971;285:1182-6.
2. Folkman J. Angiogenesis in cancer, vascular, rheumatoid and other disease. Nat Med 1995;1(1):27-31.
3. Folkman J. Angiogenesis. Annu Rev Med 2006;57:1-18.
4. Ferrara N, Hillan KJ, Gerber HP, Novotny W. Discovery and development of bevacizumab, an anti-VEGF antibody for treating cancer. Nat Rev Drug Discov 2004;3:391-400.
5. Kerbel R. Molecular origins of cancer: tumor angiogenesis. N Engl J Med 2008;358(19):2039-49.
6. Jain RK. Normalization of tumor vasculature: an emerging concept in antiangiogenic therapy. Science 2006;307:58-62.
7. Cristofanilli M, Charnsangavej C, Nortobagyi GN. Angiogenesis modulation in cancer research: novel clinical approaches. Nat Rev Drug Discov 2002;1:415-26.
8. Olive KP, Jacobetz MA, Davidson CJ, Gopinathan A, McIntyre D, Honess D, et al. Inhibition of hedgehog signaling enhances delivery of chemotherapy in a mouse model of pancreatic cancer. Science 2009 Jun 12;324(5933):1457-61.
9. Palmowski M, Huppert J, Hauff P, Reinhardt M, Schreiner K, Socher MA, et al. Vessel fractions in tumor xenografts depicted by flow- or contrast-sensitive three-dimensional high-frequency doppler ultrasound respond differently to antiangiogenic treatment. Cancer Res 2008 Sep 1;68(17):7042-9.
10. Loveless ME, Whisenant JG, Wilson K, Lyshchik A, Sinha TK, Gore JC, et al. Coregistration of ultrasonography and magnetic resonance imaging with a preliminary investigation of the spatial colocalization of vascular endothelial growth factor receptor 2 expression and tumor perfusion in a murine tumor model. Mol Imaging 2009;8(4):187-98.

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