ログイン
ランキング
お知らせ
ログイン
文献詳細
文献概要
特集 循環器疾患の画像診断—現状と進歩 Ⅷ.トピックス
3次元血流解析の開発,診断・治療への応用
著者: 板谷慶一12
所属機関: 1京都府立医科大学心臓血管外科心臓血管血流解析学講座成人先天性センター 2株式会社Cardio Flow Design
ページ範囲:P.488 - P.498
文献購入ページに移動Point
・血流解析は流体力学の基盤である数理理論と循環器病学の基盤である循環生理学に深く根ざした学問であり,技術開発にはこれらの基礎学問のコンセプトを要する.
・血流解析は流体力学同様「場の理論」であり,統計学や機械学習などのデータサイエンスとは異なるアプローチであるが,まだ経験の蓄積やデータが十分でない疾患の診断・治療には威力を発揮しうる.
・MRIや超音波計測に基づく血流解析は心機能診断の一環として系統的な血流診断をするべきであり,CFDシミュレーションでは非解剖学的な血行再建などの「仮想手術シミュレーション」が可能である.
・血流解析は流体力学の基盤である数理理論と循環器病学の基盤である循環生理学に深く根ざした学問であり,技術開発にはこれらの基礎学問のコンセプトを要する.
・血流解析は流体力学同様「場の理論」であり,統計学や機械学習などのデータサイエンスとは異なるアプローチであるが,まだ経験の蓄積やデータが十分でない疾患の診断・治療には威力を発揮しうる.
・MRIや超音波計測に基づく血流解析は心機能診断の一環として系統的な血流診断をするべきであり,CFDシミュレーションでは非解剖学的な血行再建などの「仮想手術シミュレーション」が可能である.
参考文献
1) Itatani K:Advances in Hemodynamic Research. Nova Science Publisher, New York, 2015
2) Itatani K, Miyazaki S, Furusawa T, et al:New imaging tools in cardiovascular medicine:computational fluid dynamics and 4D flow MRI. Gen Thorac Cardiovasc Surg 65:611-621, 2017
3) 板谷慶一,山岸正明,夜久 均:先天性心疾患治療における血流解析手法の役割.日本小児循環器学会雑誌33:371-384, 2017
4) Landau LD, Lifshitz EM:Fluid Mechanics, 2nd Edition. Butterworth Heinemann, Oxford, 1987
5) Wei F, Westerdale J, McMahon EM, et al:Weighted least-squares finite element method for cardiac blood flow simulation with echocardiographic data. Comput Math Methods Med 2012:371315, 2012
6) Miyazaki S, Itatani K, Furusawa T, et al:Validation of numerical simulation methods in aortic arch using 4D Flow MRI. Heart Vessels 32:1032-1044, 2017
7) 梅津光生:Bloody Engineerの医療への挑戦.人工臓器39:9-11, 2010
8) 松本洋一郎:平成29年度 次世代医療機器・再生医療等製品 評価指標作成事業 血流シミュレーションソフトウェア審査WG報告書.http://dmd.nihs.go.jp/jisedai/blood_flow/H29_blood_flow_report.pdf
9) Sugawara M, Kajiya F, Kitabatake A, et al:Blood flow in the heart and large vessels, Springer Japan, 1989
10) Kilner PJ, Yang GZ, Mohiaddin RH, et al:Helical and retrograde secondary flow patterns in the aortic arch studied by three-directional magnetic resonance velocity mapping. Circulation 88:2235-2247, 1993
11) Van Haesdock JM, Mertens L, Sizaire R, et al:Comparison by computerized numeric modeling of energy losses in different Fontan connections. Circulation 92(Suppl Ⅱ):Ⅱ322-Ⅱ326, 1995
12) Bove EL, de Leval MR, Migliavacca F, Computational fluid dynamics in the evaluation of hemodynamic performance of cavopulmonary connections after the Norwood procedure for hypoplastic left heart syndrome. J Thorac Cardiovasc Surg 126:1040-1047, 2003
13) Pekkan K, de Zelcourt D, Ge L, et al:Physics-driven CFD modeling of complex anatomical cardiovascular flows-a TCPC case study. Ann Biomed Eng 33:284-300, 2005
14) Hasan A, Kolahdouz EM, Enquobahrie A, et al:Image-based immersed boundary model of the aortic root. Med Eng Phys 47:72-84, 2017
15) Garcia D, Del Almano JC, Tanne D, et al:Two-dimensional intraventricular flow mapping by digital processing conventional color-Doppler echocardiography images. IEEE Trans Med Imaging 29:1701-1713, 2010
16) Itatani K, Okada T, Uejima T, et al:Intraventricular Flow Velocity Vector Visualization Based on the Continuity Equation and Measurements of Vorticity and Wall Shear Stress. Jpn J Appl Phys 52:07HF16-07HF16-6, 2013
17) Kim HB, Hertzberg J, Lanning C, et al:Noninvasive measurement of steady and pulsating velocity profiles and shear rates in arteries using echo PIV:in vitro validation studies. Ann Biomed Eng 32:1067-1076, 2004
18) Greenberg NL, Vandervoort PM, Firstenberg MS, et al:Estimation of diastolic intraventricular pressure gradients by Doppler M-mode echocardiography. Am J Physiol Heart Circ Physiol 280:H2507-H2515, 2001
19) Shigemitsu S, Takahashi K, Yazaki K, et al:New insight into the intraventricular pressure gradient as a sensitive indicator of diastolic cardiac dysfunction in patients with childhood cancer after anthracycline therapy. Heart Vessels, 2019. https://doi.org/10.1007/s00380-018-01332-7
20) Valen-Sendstad K, Bergersen AW, Shimogonya Y, et al:Real-World Variability in the Prediction of Intracranial Aneurysm Wall Shear Stress:The 2015 International Aneurysm CFD Challenge 9:544-564, 2018
21) Koo BK, Erglis A, Doh JH, et al:Diagnosis of ischemia-causing coronary stenoses by noninvasive fractional flow reserve computed from coronary computed tomographic angiograms. Results from the prospective multicenter DISCOVER-FLOW(Diagnosis of Ischemia-Causing Stenoses Obtained Via Noninvasive Fractional Flow Reserve)study. J Am Coll Cardiol 58:1989-1997, 2011
22) Nørgaard BL, Leipsic J, Gaur S, et al:Diagnostic performance of noninvasive fractional flow reserve derived from coronary computed tomography angiography in suspected coronary artery disease:the NXT trial(Analysis of Coronary Blood Flow Using CT Angiography:Next Steps). J Am Coll Cardiol 63:1145-1155, 2014
23) Hirohata K, Kano A, Goryu A, et al:A novel CT-FFR method for the coronary artery based on 4D-CT image analysis and structural and fluid analysis. SPIE Medical Imaging 9412:1-15, 2015
24) Takigami M, Itatani K, Nakanishi N, et al:Evaluation using a four-dimensional imaging tool before and after pulmonary valve replacement in a patient with tetralogy of Fallot:a case report. J Med Case Rep 13:30, 2019
25) Garcia D, Pibarot P, Dumesnil JG, et al:Assessment of aortic valve stenosis severity:A new index based on the energy loss concept. Circulation 101:765-771, 2000
26) Itatani K, Ono M:Blood flow visualizing diagnostic device. WO2013077013A1 PCT/JP2012/063484. https://patents.google.com/patent/WO2013077013A1/en
27) Bahlmann E, Gerdts E, Cramariuc D, et al:Prognostic value of energy loss index in asymptomatic aortic stenosis. Circulation 127:1149-1156, 2013
28) Nakashima K, Itatani K, Kitamura T, et al:Energy dynamics of the intraventricular vortex after mitral valve surgery. Heart Vessels 32:1123-1129, 2017
29) Honda T, Itatani K, Miyaji K, et al:Assessment of the vortex flow in the post-stenotic dilatation above the pulmonary valve stenosis in an infant using echocardiography vector flow mapping. Eur Heart J 35:306, 2014
30) Nabeta T, Kakizaki R, Itatani K, et al:Four-Dimensional Blood Flow Analysis in Patients with Dilated Cardiomyopathy:A Cardiac Magnetic Resonance Flow Study. J Cardiac Fail 22:S177, 2016
31) Shibata M, Itatani K, Hayashi T, et al:Flow Energy Loss as a Predictive Parameter for Right Ventricular Deterioration Caused by Pulmonary Regurgitation After Tetralogy of Fallot Repair. Pediatr Cardiol 39:731-742, 2018
32) Pasipoularides A:Heart's Vortex:Intracardiac Blood Flow Phenomena. PMPH-USA, North Carolina, 2010
33) Sakajo T, Yokoyama T:Word representation of streamline topologies for structurally stable vortex flows in multiply connected domains. Proceedings of the Royal Society A:Mathematical, Physical & Engineering Sciences 469:20120558, 2013
34) Weinberg S:The Quantum Theory of Fields, Volume 2:Modern Applications. Cambridge University Press, Cambridge, 1996
35) Honda T, Itatani K, Takanashi M:Contributions of Respiration and Heartbeat to the Pulmonary Blood Flow in the Fontan Circulation. Ann Thorac Surg 102:1596-1606, 2016
36) Numata S, Itatani K, Yamazaki S, et al:Blood flow analysis of the aortic arch using computational fluid dynamics. Euro J Cardiothorac Surg 49:1578-1585, 2016
37) 久田俊明,野口裕久:非線形有限要素法の基礎と応用.丸善,1996
38) Bazilevs Y, Takizawa K, Tezduyar TE:Computational Fluid-Structure Interaction:Methods and Applications(Wiley Series in Computational Mechanics). Wiley, Hoboken, 2013
39) Takei Y, Itatani K, Miyazaki S, et al:Four-dimensional flow magnetic resonance imaging analysis before and after thoracic endovascular aortic repair of chronic type B aortic dissection. Interact Cardiovasc Thorac Surg 28:413-420, 2019
掲載誌情報
