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博士論文
Realization of 3D image reconstruction from transillumination images of animal body
国立国会図書館館内限定公開
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DOI[10.14943/doctoral.k11491]のデータに遷移します
Realization of 3D image reconstruction from transillumination images of animal body
- 国立国会図書館永続的識別子
- info:ndljp/pid/8951699
- 資料種別
- 博士論文
- 著者
- Tran, Trung Nghia
- 出版者
- Hokkaido University
- 出版年
- 2014-06-30
- 資料形態
- デジタル
- ページ数・大きさ等
- -
- 授与大学名・学位
- 北海道大学,博士(工学)
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資料に関する注記
一般注記:
- Three-dimensional (3D) imaging with X-ray or MRI has contributed greatly not only to medical diagnosis, but also to life science. The number of experi...
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デジタル
- 資料種別
- 博士論文
- 著者・編者
- Tran, Trung Nghia
- 出版年月日等
- 2014-06-30
- 出版年(W3CDTF)
- 2014-06-30
- 並列タイトル等
- 生体透視像からの3D像再構成の実現
- 寄与者
- 清水, 孝一平田, 拓工藤, 信樹
- 授与機関名
- 北海道大学
- 授与年月日
- 2014-06-30
- 授与年月日(W3CDTF)
- 2014-06-30
- 報告番号
- 甲第11491号
- 学位
- 博士(工学)
- 博論授与番号
- 甲第11491号
- 本文の言語コード
- eng
- NDC
- 対象利用者
- 一般
- 一般注記
- Three-dimensional (3D) imaging with X-ray or MRI has contributed greatly not only to medical diagnosis, but also to life science. The number of experimental animals killed for experimentation would be reduced if the animalsʟ internal structures can be visualized non-invasively. In transil-lumination imaging using near-infrared (NIR) light, the location of internal bleeding, infection, and angiogenesis can be visualized. Functional imaging is also possible using spectroscopic principles.With specific contrast media, the usefulness of NIR imaging is expanded significantly. However, the NIR transillumination technique has not been used widely. The major reason for that relative lack of use is the difficulty of the strong scattering in tissues. In transillumination images, the deeper structure is blurred and cannot be differentiated from the shallower and less-absorbing structure. To overcome this problem, great effort has been undertaken to develop optical computed tomography (optical CT) techniques. The typical technique for a macroscopic structure is diffuse optical tomography (DOT).Using this technique, cross-sectional imaging of human breasts and infant heads was achieved. Once the cross-sectional images become available, 3D imaging is possible. However, current techniques require great computational effort such as finite element method calculation, and large devices such as numerous fiber bundles around the object body.It would be possible to reconstruct the 3D structure with a common filtered back-projection algorithm and with a CCD or CMOS camera if the scattering effect in transillumination images can be suppressed effectively. They require much simpler and more compact device as well as much less computational effort. This study proposes the 3D imaging of internal absorbing structure of a small experimental animal from two-dimensional (2D) NIR transillumination images using new scatteringsuppression techniques. This thesis presents the principle, implementation, and the results to show thefeasibility of the proposed method.For scattering suppression, the deconvolution technique using the point spread function (PSF) is effective. In previous study, the PSF for the light source located inside the medium had been derived by applying the diffusion approximation to the equation of transfer. With a known depth of the light source in a diffuse medium, the light distribution can be recovered clearly through an interstitial tissue by the deconvolution with this PSF. Therefore, realization of the 3D imaging from the transillumination images can be expected if this light-source PSF can be applied to the transillumination image of light-absorbing structure. Through theoretical and experimental study, the applicability of the PSF for the light source to the transillumination images of the light-absorbing structure was confirmed. The effectiveness of this technique was also confirmed in the experiments with a tissue-equivalent phantom and animal tissue.The PSF is depth-dependent, and the technique explained above was applicable only for an object with known internal structure. To expand the applicability of this technique, new algorithms were devised. An observed transillumination image is deconvoluted with the PSFs of different depths. Then the deconvoluted images are summed up to produce a new image that serves as a projection image in cross-sectional reconstruction. The projection image contains the projection of the true absorption dis-tribution and the incompletely deconvoluted projection as well. To suppress the effect of this erroneous projection, an erasing process was devised. An initial cross-sectional image is reconstructed from the projection images obtained from many orientations. It is used as a template to erase the erroneous distribution in the cross-section. After the application of this erasing process, a new improved projection image is formed in which the effect of the erroneous distribution is suppressed effectively. Using the projections from many orientations obtained in this process, an improved cross-sectional image can bereconstructed. With the cross-sectional images at different heights, the 3D image can be reconstructed.The feasibility of the proposed technique was examined in a computer simulation and an experiment with a model phantom. The results demonstrated the effectiveness of the proposed technique. Finally, the applicability of the proposed technique to a living animal was examined. An anesthetized mouse was fixed in a transparent cylinder. To produce a transillumination image of good quality, a light trap in the cylinder was devised. Using the proposed technique, the 3D structure of the mouse abdomen was reconstructed. High-absorbing organs such as the kidneys and parts of the liver became visible.Results of this study suggest that a new optical CT having different features from those of currentlyavailable techniques is possible. This simple system can provide a cross-sectional image and reconstruct the 3D structure of internal organ in the mouse body. It can provide a useful and safe tool for the functional imaging of internal organs of experimental animals and for optical CT imaging of the near-surface structure of a human body.(主査) 特任教授 清水 孝一, 教授 平田 拓, 准教授 工藤 信樹情報科学研究科(生命人間情報科学専攻)
- DOI
- 10.14943/doctoral.k11491
- 国立国会図書館永続的識別子
- info:ndljp/pid/8951699
- コレクション(共通)
- コレクション(障害者向け資料:レベル1)
- コレクション(個別)
- 国立国会図書館デジタルコレクション > デジタル化資料 > 博士論文
- 収集根拠
- 博士論文(自動収集)
- 公開開始日(W3CDTF)
- 2015-03-03
- 受理日(W3CDTF)
- 2015-02-03T05:25:05+09:00
- 記録形式(IMT)
- PDF
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