In Vivo Simultaneous Imaging of Vascular Pool and Hypoxia with a HT-29 Tumor Model: the Application of Dual-Isotope SPECT/PET/CT
Keywords:
64Cu-ATSM, hypoxia, dual-isotope imaging, PET, SPECT, 99mTc-HSA, vascularity.Abstract
Investigation of vascularity and hypoxia in tumors is important in understanding cancer biology to developthe therapeutic strategies in cancer treatment.
------------------------------------------------------------------------
*Corresponding author .
Recently, an imaging technology with the VECTor SPECT/PET/CT small-animal scanner (MILabs) has been developed to obtain simultaneous images usingtwodifferent tracers labeled with SPECT and PET nuclides, respectively. In this study, we developed amethod to simultaneously visualize vascularity and hypoxia witha human colon carcinoma HT-29tumor-bearing mouse model with 99mTc-labeled human serum albumin (99mTc-HSA) to detect blood pool, and 64Cu-diacetyl-bis (N4-methylthiosemicarbazone) (64Cu-ATSM) to detect the over-reduced conditionsunder hypoxia, by applying this SPECT/PET/CT technology.Prior to the in vivo experiments, a phantom study was conducted to confirmquantitativity of the 99mTc/64Cu dual-isotope imaging with the SPECT/PET/CT system,by comparing radioactivities detected by SPECT/PET/CT system and those of standards under the conditions of wide range of radioactivities and various content ratios, in our settings. An in vivoimaging study was conducted with HT-29 tumor-bearing mice. Both 64Cu-ATSM (37 MBq) and 99mTc-HSA (18.5 MBq) were intravenously injected into a mouse (n = 4) at 1 h and 10 min, respectively, before scanning for 20 min; the 99mTc/64Cu dual-isotope SPECT/PET/CT images were then obtained.The phantom study demonstrated that this system has high quantitativity, even when 2 isotopes co-existed and the content ratio was changed over a wide range, indicating the feasibility for in vivo experiments. In vivoSPECT/PET/CT imaging with 64Cu-ATSM and 99mTc-HSA visualized the distribution of each probe and showed that 64Cu-ATSM high-uptake regions barely overlapped with 99mTc-HSA high-uptake regions within HT-29 tumors.We developed a method to simultaneously visualize vascularity and hypoxia within HT-29tumors using in vivodual-isotope SPECT/PET/CT imaging. This methodology would be useful for studies oncancer biology with mouse tumor models anddevelopment of the treatment strategies against cancer.
Examination of vascularity and hypoxia within in vivotumors is important in understanding the biology of cancer anddevelopmentof the therapeutic strategies in cancer treatment. For hypervascular tumors, antiangiogenic therapy and antivascular therapy are promising approaches. For antiangiogenic therapy, the anti-vascular endothelial growth factor antibody bevacizumab is now clinically used worldwide [1-4], and for antivascular therapy, a clinical trial withcombrestatin A4 phosphate is conducted[5]. For hypovascular tumor, which is usually associated with hypoxia, intensive treatment is necessary, since tumor hypoxia is reportedly resistant to chemotherapy and radiotherapy [6-8]. In recent years, several therapeutic methods have been proposedto damage to hypoxic regions within tumors, such as intensity modulated radiation therapy with hypoxia positron emission tomography (PET) imaging [9, 10], and carbon-ion radiotherapy, which is able to damage tumor cells even in the absence of oxygen by high linear energy transfer beam [11, 12]. However, considering the difficulty of cancer radical cure at the present moment, more effective drugs and treatment methods for antiangiogenic, antivascular, and antihypoxia therapies need to be developed. In addition, combinations of these therapies would be effective approaches, since they can attacktumor vascularity and hypoxia closely linked each other.However, it is still difficult to observe tumor vascularity and hypoxia both coincidently and concisely in in vivo tumor-bearing mouse model.
Recently, a technology of single-photon emission computed tomography/positron emission tomography/computed tomography(SPECT/PET/CT) imaging with the VECTor small-animal scanner, launched from MILabs (Utrecht, Netherlands), has been reportedto obtain truly simultaneous images with twotracers labeled with SPECT and PET nuclides, respectively. Conventionally, dual-isotope imaging studies with SPECT and PET have been performed by obtaining each image independently with 2 separate systems [13, 14]. In contrast, the VECTor system is equipped with a clustered pinhole collimator, which dramatically reduces pinhole-edge penetration of high-energy annihilation ?-photons from PET nuclides and enables it to detect high-energy ?-photons derived from PET nuclides, in a manner similar to SPECT nuclides, and to obtain high-resolution images from positron emitters and single-photon emitters at the same time by separating the images based on the photon energy [15, 16]. Thus, this system has a novel concept to make images of PET nuclides, compared to the typical PET system, which measures the coincidence of annihilation ?-photons. Goorden et al. have reported that this system shows high spatial resolution, with 0.8 mm for PET nuclides and 0.5 mm for SPECT nuclides [15]. Miwa et al. also confirmed its performance in simultaneous detection of 99mTc and 18F using this system [17].
In this study, we developed a methodology to easily observe intratumoralvascularity and hypoxia in a simultaneous manner,by applyingthis SPECT/PET/CT technology. We used 99mTc-labeled human serum albumin (99mTc-HSA) labeled with a SPECT nuclide 99mTc (half-life = 6.0 h; 140 keV ?-ray: 89%) to visualize tumor vascularity by detecting blood pool [18]. The 99mTc-HSAhas been reported to detect tumor blood pool in many types of cancer, including colon cancer, renal cell carcinoma, and liver tumor in both preclinical and clinical studies [19-21]. We also used 64Cu-diacetyl-bis (N4-methylthiosemicarbazone) (64Cu-ATSM), labeled with a PET nuclide 64Cu (half-life = 12.7 h; ?+-decay: 17.4%; ??-decay: 38.5%; and electron capture: 43%) [22], to detect tumor hypoxia. The Cu-ATSM, labeled with Cu radioisotopes, such as 60Cu, 62Cu, and 64Cu, has been developed as an imaging agent targeting hypoxic regions in tumors for use with PET [23-26].Many studies have demonstrated that Cu-ATSM accumulation is associated with hypoxic conditions of tumor in vitro and in vivo[26-29]. The mechanism of radiolabeled Cu-ATSM accumulation has been studied: Cu-ATSM has small molecular sizeand high membrane permeability, and thus rapidly diffuses into cells and is reduced and trapped within cells under highly reduced intracellular conditions such as hypoxia [24, 29-31]. A clinical study with 62Cu-ATSM demonstrated that high levels of hypoxia-inducible factor-1? (HIF-1?) expression were found in Cu-ATSM uptake regions in the tumors of patients with glioma [32]. In this study, we performed simultaneous in vivo imaging using a SPECT/PET/CT with 99mTc-HSA and 64Cu-ATSM for detecting tumor vascularity and hypoxia with a HT-29 tumor-bearing mouse model.
References
. Kuroda J, Kuratsu J, Yasunaga M, Koga Y, Kenmotsu H, Sugino T, et al.
. Mukherji SK.
. Leu K, Enzmann DR, Woodworth DC, Harris RJ, Tran AN, Lai A, et al.
. Jennings D, Raghunand N, Gillies RJ.
. Rustin GJ, Galbraith SM, Anderson H, Stratford M, Folkes LK, Sena L, et al.
. Brown JM.
. Phillips RM, Loadman PM, Cronin BP.
. H
. Chao KSC, Bosch WR, Mutic S, Lewis JS, Dehdashti F, Mintun MA, et al.
. Hendrickson K, Phillips M, Smith W, Peterson L, Krohn K, Rajendran J.
. Nakano T, Suzuki Y, Ohno T, Kato S, Suzuki M, Morita S, et al.
. Furusawa Y, Fukutsu K, Aoki M, Itsukaichi H, Eguchi-Kasai K, Ohara H, et al.
. Lu Y, Yang K, Zhou K, Pang B, Wang G, Ding Y, et al.
. Magota K, Kubo N, Kuge Y, Nishijima K-i, Zhao S, Tamaki N.
. Goorden MC, Have Fvd, Kreuger R, Ramakers RM, Vastenhouw B, Burbach JPH, et al.
. Walker MD, Goorden MC, Dinelle K, Ramakers RM, Blinder S, Shirmohammad M, et al.
. Miwa K, Inubushi M, Takeuchi Y, Katafuchi T, Koizumi M, Saga T, et al.
. Schmitt A, Bernhardt P, Nilsson O, Ahlman H, K
. Welt S, Divgi CR, Real FX, Yeh SD, Garin-Chesa P, Finstad CL, et al.
. Oosterwijk E, Bander NH, Divgi CR, Welt S, Wakka JC, Finn RD, et al.
. Levin VA, Freeman-Dove M, Landahl HD.
. Lewis JS, Laforest R, Dehdashti F, Grigsby PW, Welch MJ, Siegel BA.
. Dehdashti F, Grigsby PW, Lewis JS, Laforest R, Siegel BA, Welch MJ.
. Fujibayashi Y, Taniuchi H, Yonekura Y, Ohtani H, Konishi J, Yokoyama A.
. Lewis J, Laforest R, Buettner T, Song S, Fujibayashi Y, Connett J, et al.
. Lewis JS, McCarthy DW, McCarthy TJ, Fujibayashi Y, Welch MJ.
. Burgman P, O'Donoghue JA, Lewis JS, Welch MJ, Humm JL, Ling CC.
. Lewis JS, Sharp TL, Laforest R, Fujibayashi Y, Welch MJ.
. Obata A, Yoshimi E, Waki A, Lewis JS, Oyama N, Welch MJ, et al.
. Dearling JL, Lewis JS, Mullen GE, Welch MJ, Blower PJ.
. Yoshii Y, Yoneda M, Ikawa M, Furukawa T, Kiyono Y, Mori T, et al.
. Tateishi K, Tateishi U, Sato M, Yamanaka S, Kanno H, Murata H, et al.
. Obata A, Kasamatsu S, McCarthy DW, Welch MJ, Saji H, Yonekura Y, et al.
. Yoshii Y, Furukawa T, Kiyono Y, Watanabe R, Waki A, Mori T, et al.
. Branderhorst W, Vastenhouw B, Beekman FJ.
. Ogawa K, Harata Y, Ichihara T, Kubo A, Hashimoto S.
. Yang J-T, Yamamoto K,Sadato N,Tsuchida T, Takahashi N, Hayashi N, et al.
. Zinn KR, Douglas JT, Smyth CA, Liu HG, Wu Q,Krasnykh VN, et al.
. Yoshii Y, Matsumoto H, Yoshimoto M, Furukawa T,Morokoshi Y,Sogawa C, et al.
. Tanaka T, Furukawa T, Fujieda S, Kasamatsu S, Yonekura Y, Fujibayashi Y.
. Oh M, Tanaka T, Kobayashi M, Furukawa T, Mori T, Kudo T, et al.
. Furukawa T, Yuan Q, Jin ZH,Aung W, Yoshii Y, Hasegawa S, et al.
. Lohith TG,Kudo T,Demura Y,Umeda Y,Kiyono Y, Fujibayashi Y, et al.
Downloads
Published
How to Cite
Issue
Section
License
Copyright (c) 2016 International Journal of Sciences: Basic and Applied Research (IJSBAR)
This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Authors who submit papers with this journal agree to the following terms.
