[Seite 93↓]

Literaturverzeichnis

[Abragam/61] Abragam A, The principles of nuclear magnetism, Oxford, Clarendon, 1961, 2-53- 289-305

[Agah/94] Agah R, Pearce J A, Welch A J, Motamedi M, Rate Process Model for arterial tissue thermal damage: Implications on vesse photocoagulation, Lasers Surg Med, 1994, 15: 179-184

[Amin/93] Amin Z, Donald J J, Masters A, Kant R, Steger A C, Brown S G, Hepatic Metastases: Interstitial Laser Photocoagulation with Real Time US-Monitoring and Dynamic CT Evaluation of Treatment, Radiology, 1993, 187: 339-347

[Arrhenius/1889] Arrhenius S, Über die Reaktionsgeschwindigkeit bei der Inversion von Rohrzucker in Säuren, Z. Phys. Chem., 1889, 4: 226-248

[Ascher/90] Ascher P W, Interstitial Thermal Therapy of Brain Tumors with Nd:YAG Laser under Real Time MRI Control, Laser Surgery: Advanced Characterization, Therapeutics and Systems II, 1990, 242-245

[Auphan/82] Auphan M, Nicolas J M, Tissue Ultrasonic Attenuation well modelized by a Mellin convolution, Acoustical Imag, 1982, 12: 413-422

[Bamber/77] Bamber J C, Fry M J, Hill C R, Dunn F, Ultrasonic Attenuation and Backscattering by Mammalian Organs as a Function of Time after Excision, Ultrasound Med Biol, 1977, 3: 15-20

[Bamber/79] Bamber J C, Hill C R, Ultrasonic Attenuation and Propagation Speed in Mammalian Tissues as a Function of Temperature, Ultrasound Med Biol, 1979, 5: 149-157

[Beckord/98] Beckord P, Höfelmann G, Luck O H, Franken D, Temperature and flow fields measurement using ultrasonic computer tomography, Heat and Mass Transfer, 1998, 33: 395-403

[Blüml/93] Blüml S, Schad L R, Stepanow B, Lorenz W J, Spin-lattice relaxation time measurement by means of a turboFlash technique, Magn Reson Med, 1993, 30: 289-295


[Seite 94↓]

[Bosman/91] Bosman S, Phoa S S K, Bosma A, van Gemert M J C, Effect of percutaneous interstitial thermal laser on normal liver of pigs: sonographic and histopathological correlations, Br J Surg, 1991, 78: 572-575

[Bowen/77] Bowen T, Connor W G, Nasoni R L, Pifer A E, Sholes R R, Measurement of the temperature dependence of the velocity of ultrasound in soft tissues, 2nd Int Symp on Ultrasonic Tissue Characterization, 1977,

[Bowen/87] Bowen T, Acoustic radiation temperature for noninvasive thermometry, Automedica, Band 4, 1987, 8: 247-267

[Bridal/97] Bridal S L, Fornes P, Bruneval P, Berger G, Parametric (Integrated Backscatter and Attenuation) Images Constructed using Backscattered Radio Frequency Signals (25-56 MHz) from Human Aorta In Vitro, Ultrasound Med Biol, Band 2, 1997, 23: 215-229

[Bush/93] Bush N L, Rivens I, Ter Haar G R, Bamber J C, Acoustic Properties of Lesions Generated with an Ultrasound Therapy System, Ultrasound Med Biol, Band 9, 1993, 19: 789-801

[Busse/99] Busse H, Rassek M, Grunst A, Kahn T, Schwarzmaier H J, Improved quantitative MR thermometry using a 1,5 T scanner to monitor cooled applicator systems during laser induced interstitial thermotherapy (LITT), SPIE S14, 1999, 3594: 196-203

[Cardoso/83] Cardoso J F, Fink M, Diffraction Correction in Pulse Echo Attenuation Measurements, IEEE Ultrasonics Symp, 1983, 841-846

[Cespedes/95] Cespedes I, Huang Y, Ophir J, Spratt S, Methods for estimation of subsample time delays of digitized echo signals, Ultrason Imag, 1995, 17: 142-171

[Cline/94] Cline H E, Hynyen K, Hardy C J, Watkins R D, Schenk J F, MR temperature Mapping of focused ultrasound surgery, Magn Reson Med, 1994, 31: 628-636

[Cloostermans/83] Cloostermans M J, Thijssen J M, A Beam Corrected Estimation of the Frequency Dependent Attenuaton of Biological Tissues From Backscattered Ultrasound, Ultrason Imag, 1983, 5: 136-147


[Seite 95↓]

[Dachman/90] Dachman A H, McGehee J A, Beam T E, Burris J A, Powell D A, US-guided Percutaneous Laser Ablation of Liver Tissue in a chronic Pig Model, Radiology, 1990, 176: 129-133

[Davis/85] Davis B J, Lele P P, An acoustic phase shift technique for the noninvasive measurement of temperature changes in tissues, IEEE Ultrason Symp Proc, 1985, 921-924

[Davies/89] Davies M, Dowden J, Steger A, Kapadia P, Whiting P, A mathematical model for interstitial laser treatment of tumors using four fibers, Laser Med Sci, 1989, 4: 41-53

[Delannoy/91] Delannoy J, Chen C N, Turner R, Levin R L, LeBihan D, Noninvasive Temperature imaging ussing diffusion MRI, Magn Reson Med, 1991, 19: 333-339

[De Poorter/94] De Poorter J, De Wagter C, De Deene Y, Thomson C, Stahlberg F, Achten E, The proton resonance frequency shift method compared with molecular diffusion for quantitative measurement of two dimensional time dependent temperature distribution in phantom, J Magn Reson, 1994, 103: 234-241

[De Poorter/94A] De Poorter J, De Wagter C, De Deene Y, Thomson C, Stahlberg F, Eric A, Noninvasive MRI thermometry with the proton resonance frequency shift method: in vivo results in human muscle, J Magn Reson Imaging, 1994, 103: 234-241

[Duck/90] Duck F A, Physical Principles of Tissue, London, Academic Press, 1990

[Dunn/61] Dunn F, Fry W J, Ultrasonic Absorption and Reflection by Lung Tissue, Physics Med Biol, 1961, 5: 401-410

[Fink/83] Fink M, Hottier F, Cardoso J F, Ultrasonic signal processing for in vivo attenuation measurement: short time fourier analysis, Ultrason Imag, 1983, 5: 117-135

[Flax/81] Flax S W, Glover G H, Pelc J J, Textural variation in B-Mode ultrasonography, Ultrason Imag, 1981, 3: 235-257

[Freese/68] Freese M, Makow D, Ultrasonic Backscatter in Fresh and Thawed Animal Tissue, J Fish Res Bd Canada, 1968, 25: 605-607


[Seite 96↓]

[Frenzel/96] Frenzel T, Roth K, Kossler S, Radüchel B, Bauer H, Platzek J, Weinmann H, Noninvasive Temperature Measurement in vivo using a temperature-sensitive lanthanide complex and 1H magnetic resonance spectroscopy, Magn Reson Med, 1996, 35: 364-369

[Fried/96] Fried M P, Morrison P R, Hushek S G, Kernahan G A, Jolesz F A, Dynamic T1 weighted magnetic resonance imaging of interstitial laser photocoagulation in the liver: observations on in vivo temperature sensitivity, Lasers Surg Med, 1996, 18: 410-419

[Gammel/79] Gammel P M, Le Croisette H, Heyser R C, Temperature and Frequency Dependence of Ultrasonic Attenuation in Selected Tissues, Ultrasound Med Biol, 1979, 5: 269-272

[Ghaedian/97] Ghaedian R, Decker E A, McClements D J, Use of Ultrasound to determine cod fillet composition, J Food Sci., Band 3, 1997, 62: 500-504

[Gewiese/94] Gewiese B, Beuthan J, Fobbe F, Stiller D, Müller G, Böse-Landgraf J, Wolf KJ, Deimling M, , Magnetive Resonance Imaging – Controlled Laser Induced Interstitial Thermotherapy, Invest Radiol, 1994, 29: 345-351

[Greenspan/59] Greenspan M, Tschiegg C E, Tables of the speed of sound in water, J Acoust Soc Am, 1959, 31: 75-76

[Grimm/98] Grimm M, Lahanas M, Richtscheid M, Walter S, , Freihand-Akquisition, Rekonstruktion und Visualisierung von 3D-Ultraschall, Medizin im Bild, 1998, 3: 7-13

[Goodsitt/81] Goodsitt M M, Madsen E L, Zagzebski J A, A three dimensional model for generating the texture in B-Scan Ultrasound Images, Ultrason Imag, 1981, 5: 253-279

[Goss/64] Goss S A, Johnson A L, Dunn F, Comprehensive compilation of empirical ultrasonic properties of mammalian tissues, J Acoust Soc Amer, Band 2, 1978, 64: 423-457

[Goss/80] Goss S A, Johnson A L, Dunn F, Compilation of empirical ultrasonic properties of mammalian tissues II, J Acoust Soc Amer, Band 1, 1980, 68: 93-108


[Seite 97↓]

[Hachiya/92] Hachiya H, Ohtsuki S, Tanaka M, Dunn F, Determination of Sound Speed in Biological Tissues Based on Frequency Analysis of Pulse Response, J Acoust Soc Am, 1992, 88: 1679-1686

[Hall/90] Hall A S, Prior P V, Hand J W, Young I R, Dickinson R J, Observation by MR Imaging of in vivo temperature changes induced by radiofrequency hyperthermia, J Comput Assist Tomogr, 1990, 10: 469-472

[Harth/97] Harth T, Kahn T, Rassek M, Schwabe B, Schwarzmaier HJ, Lewin JS, Mödder U, Determination of laser induced temperature distributions using echo-shifted turboFLASH, Magn Reson Med, 1997, 38: 238-245

[Henriques/47] Henriques F C, Studies of thermal injury V: the predictability and significance of thermally induced rate processes leading to irreversible epidermal injury, Arch. Pathol, 1947, 43: 489-502

[Hill/67] Hill J E, Leitmann J D, Sunderland JE, Thermal conductivity of various meats, Foot Technol, 1967, 2: 1143-1148

[Hill/91] Hill D L G, Hawkes D J, Hardingham C R, The use of anatomical knowledge to register 3D blood vessel data from DAS with MR images, 1991, 1445: 348-357

[Hindman/66] Hindman J C, Proton resonance shift of water in the gas and liquid states, J Chem Phys, 1966, 44: 4582-4592

[Hodges/94] Hodges T C, Detmer P R, Burns D H, Beach K W, Strandness D E, Ultrasonic Three-Dimensional Reconstruction: In-Vitro and In Vivo Volume and Area Measurement, Ultrasound Med Biol, 1994, 20: 719-729

[Jäger/96] Jäger L, Müller-Lisse G U, Gutmann R, Feyh J, Thoma M, Reeiser M, Erste Ergebnisse der MRT-gesteuerten laserinduzierten interstitiellen Thermotherapie von Kopf und Hals Tumoren, Radiologe, 1996, 36: 236-244

[Jacques/91] Jacques S L, Newman C, He X Y, Thermal Coagulation of Tissue, Liver studies indicate a distribution of rate parameters not a single rate parameter describes the coagulation process, Proc. Annual Winter Meeting of the American Society of Mechanical Engineers, 1991,


[Seite 98↓]

[Johnson/74] Johnson F H, Eyring H, Stover B J, The theory of rate processes in biology and medicine, New York, 1974

[Jolesz/88] Jolesz F A, Bleier A R, Jakab P, Ruenzel P W, Huttl K, Jako G J, MR Imaging of Laser-Tissue Interactions, Radiology, 1988, 168: 249-253

[Jones/84] Jones J P, Leeman S, Ultrasonic tissue characterization: a review, Acta Elektronica, Band 1-2, 1984, 26: 3-31

[Kahn/96] Kahn T, Bettag M, Harth T, Schwabe B, Schwarzmaier H J, Mödder U, Laserinduzierte interstitielle Thermotherapie von zerebralen Tumoren unter Kernspintomographischer Kontrolle, Radiologe, 1996, 36: 713-721

[Kahn/97] Kahn T, Harth H, Schwarzmaier H J, Mödder U, MR Tomographische Temperaturquantifizierung bei 1,5 T in vitro: Vergleich von schnellen T1 Parameterbildern und einer Phasensensitiven Sequenz, Fortschr Röntgenstr, 1997, 167: 187-193

[Konstanczak/97] Konstanczak P, Wust P, Sander B, Schründer S, Frenzel T, Wlodarczyk W, Vogl T, Müller G, Felix R, Thermometrie durch Messung der chemischen Verschiebung eines Lanthanidenkomplexes, Strahlenther Onkol, 1997, 173: 106-116

[Kuc/76] Kuc R, Schwartz M, Micsky L V, Parametric estimation of the acoustic attenuation coefficient slope for soft tissue, IEEE Ultrason Symp Proc, 1976, 44-47

[Kuc/77] Kuc R, Schwartz M, Finby N, Dain F, Variance reduction in the characterization of liver tissue using reflected ultrasound signals, IEEE Ultrason Symp Proc, 1977, 219-222

[Kuc/79] Kuc R, Schwartz M, Estimating the Acoustic Attenuation Coefficient Slope for Liver from Reflected Ultrasound Signals, IEEE Trans Ultrason, Band 5, 1979, 26: 353-362

[Kuc/80] Kuc R, Clinical Application of an Ultrasound attenuation Coefficient Estimation Technique for Liver, IEEE Trans Biomed Eng, Band 6, 1980, 27: 312-319


[Seite 99↓]

[Kuc/81] Kuc R, Taylor J W, Variation of acoustic attenuation coefficient slope estimates for in vivo liver, Ultrasound Med Biol, 1981, 8: 403-412

[Kuc/84] Kuc R, Estimating the Acoustic Attenuation from Reflected Ultrasound Signals: Comparison of Spectral Shift and Spectral-Difference Approaches, IEEE Trans Acoust ASSP, Band 1, 1984, 32: 1-6

[LeBihan/89] LeBihan D, Delannoy J, Levin R L, Temperature Mapping with MRI imaging of molecular diffusion: application to hyperthermia, Radiology, 1989, 171: 853-857

[Lizzi/97] Lizzi F L, Astor M, Liu Tian, Deng Cheri, Coleman J D, Silverman R H, Ultrasonic Spectrum Analysis for Tissue Assays and Therapy Evaluation, Int J Imaging Syst Technol, 1997, 8: 3-10

[Maas-Moreno/95] Maas-Moreno R, Damianou-C-A, Sanghvi N T, Tissue temperature estimation in vivo with pulse echo, IEEE Ultrason Symp Proc, Band 1636, 1995, 2: 1225-1229

[Maas-Moreno/96] Maas-Moreno R, Damianou-C-A, Noninvasive temperature estimation in tissue via ultrasound echo shifts: Part I, Analytical model, J Acoust Soc Am, Band 4, 1996, 100: 2514-2521

[Maas-Moreno/96a] Maas-Moreno R, Damianou-C-A, Sanghvi N T, Noninvasive temperature estimation in tissue via ultrasound echo shifts: Part II, In vitro studies, J Acoust Soc Am, Band 4, 1996, 100: 2522-2530

[Maklad/84] Maklad N F, Ophir J, Balsara V, Attenuation of Ultrasound in normal and diffuse Liver Disease, Ultrason Imag, 1984, 6: 117-125

[Matthewson/87] Matthewson K K, Coleridge-Smith P, O’Sullivan PJ P, Biological effects of intrahepatic neodymium:yttrium-aluminium garnet laser photocoagulation in rats, Gastroenterology, 1987, 93: 550-557

[Matsumoto/94] Matsumoto R, Mulkern R V, Hushek S G, Jolesz F A, Tissue Temperature Monitoring for thermal interventional therapy: comparison of T1 weighted sequences, J Magn Reson Imaging, 1994, 4: 65-70

[Mendez/60] Mendez J, Keys A, Density and composition of mamalian tissue, Metabolism, 1960, 9: 184-188


[Seite 100↓]

[Miller/83] Miller J G, Pere J E, Mottley J G, Madaras E I, Johnston P H, Blodgett E D, Thomas L J III, Sobel B E, Myocardial Tissue Characterization: An Approach based on Quantitative Backscatter and Attenuation, IEEE Ultrason Symp Proc, 1983, 782-793

[Mitchell/45] Mitchell H H, Hamilton T S, Stegerda F R, Bean H W, The contents of the human body, J. Biol. Chem, 1945, 158: 625

[Müller/95] Müller G, Roggan A, Laser-induced interstitial thermotherapy, SPIE Print Monograph, 1995, 1-549

[Müller-Lisse/96] Müller-Lisse G U, Heuck A F, Stehling M K, MRT Monitoring vor, während und nach der interstitiellen laserinduzierten Thermotherapie der benignen Prostatahyperplasie, Radiologe, 1996, 36: 722-731

[Narayana/83] Narayana P A, Ophir J, On the frequency dependence of Attenuation in Normal and Fatty Liver, IEEE Trans Ultrason Su, Band 6, 1983, 30: 379-383

[Nasoni/82] Nasoni R L, Bowen T, Dewhirst M W, Roth H, In Vivo Temperature Dependence of the Speed of Sound in Mammalian Tissue and its Possible Use in Hyperthermia, Natl Cancer Inst Monogr, 1982, 61: 501-504

[Nasoni/87] Nasoni R L, Bowen T, Ultrasonic speed as a parameter for noninvasive thermometry, Automedica, Band 4, 1987, 8: 269-281

[Noeske/00] Noeske R, Anwendung der Hochfeld-(3-Tesla)-NMR-Tomographie: Abbildung des menschlichen Herzens und NMR-Thermographie an Phantomen für eine Tiefenhyperthermie, Dissertation Fachbereich Physik, 2000, Berlin,

[O’Donnel/77] O’Donnel M, Mimbs J W, Sobel B E, Miller J G, Ultrasonic Attenuation of myocardial Tissue: Dependence on Time after Excision and on Temperature, J Acoust Soc Am, 1977, 62: 1054-1057

[O’Donnel/79] O’Donnel M, Miller J G, Mechanism of Ultrasonic Attenuation in Soft Tissue, Ultrasonic Tissue Characterization, 1979, 37-40


[Seite 101↓]

[O’Donnel/83] O’Donnel M, Effects of Diffraction on Measurements of the Frequency-Dependent Ultrasonic Attenuation, IEEE Trans Biomed Eng, Band 6, 1983, 30: 320-325

[Olsrund/99] Olsrund J, Wirestam R, Persson B R R, Tranberg K-G, Simplified Treatment Planning for interstitial Laser Thermotherapy by disregarding light transport: A numerical study, Lasers in Surgery and Medicine, 1999, 25: 304-314

[Ophir/78] Ophir J, Maklad N F, A new stochastic C-scan technique for attenuation measurement in tissue equivalent material, Proc 23rd Ann Meet AIUM, 1978,

[Ophir/82] Ophir J, Maklad N F, Bigelow R H, Ultrasonic Attenuation Measurement of in vivo Human Muscle, Ultrason Imag, 1982, 4: 290-295

[Ophir/84] Ophir J, Shawker T H, Maklad N F, Miller J G, Flax S W, Narayana P A, Jones J P, Attenuation Estimation in Reflection: Progress and Prospects, Ultrason Imag, 1984, 6: 349-395

[Ophir/89] Ophir J, Johnson W, Yazdi Y, Shattuck D, Mehta D, Correlation artifacts in speed of sound estimation in scattering media, Ultrasound in Med & Biol, Band 4, 1989, 15: 341-353

[Ophir/91] Ophir J, Moriya T, Yazdi Y, A single transducer transaxial compression technique for the estimation of sound speed in biological tissues, Ultrason Imag, 1991, 13: 269-279

[Pennes/48] Pennes H H, Analysis of tissue and arterial blood temperatures in resting forearm, J. Appl. Physiol, 1948, 1: 93-122

[Philipp/94] Philipp C, Bollow M, Krasicka-Rohde E, Fobbe F, Berlien H P, Color-coded duplex sonography as a new method for monitoring of laser induced thermotherapy, Clinical Application of Modern Imaging Technology II, SPIE Proc, 1994, 287-294

[Porter/99] Porter B C, Rubens D J, Parker J K, Three Dimensional Frameless Fusion of Ultrasound Liver Volumes, IEEE International Ultrasonics Symposium, 1999,


[Seite 102↓]

[Ribault/98] Ribault M, Chapelon J Y, Cathignol D, Gelet A, Differential Attenuation Imaging for the Characterization of High Intensity Focused Ultrasound Lesions, Ultrason Imag, 1998, 20: 160-177

[Robinson/72] Robinson T C, Lele P P, An Analysis of lesion development in the brain and plastics by high intensity focused ultrasound at low megahertz frequencies, J Acoust Soc Am, 1972, 51: 1333-1351

[Roggan/97] Roggan A, Dosimetrie thermischer Laseranwendungen in der Medizin: Untersuchung der optischen Gewebeeigenschaften und physikalisch-mathematische Modellentwicklung, Hrsg.: Müller G, Berlien H P: Landsberg/Lech, ecomed, 1997

[Rohde/96] Rohde E, Phillip C, Berlien H P, Untersuchungen zur Farbkodierten Duplexsonografie (FKDS)-Kontrolle der Interstitiellen Laserinduzierten Thermotherapie (LITT), Lasermedizin, Band 3-4, 1996, 12: 121-129

[Sapareto/84] Sapareto S A, Dewey W C, Thermal dose determination in cancer therapy, Int J Rad Oncol Biol Phys, 1984, 10: 787-800

[Schmidt/83] Schmidt R F, Thews G, Physiologie des Menschen, 1983, Berlin, Springer,

[Seip/95] Seip R, Ebbini E E, Noninvasive estimation of tissue temperature response to heating fields using diagnostic ultrasound, IEEE Trans Biomed Eng, Band 8, 1995, 42: 828-839

[Seip/96] Seip R, VanBaren P, Cain A C, Ebbini E S, Noninvasive real-time multipoint temperature control for ultrasound phased array treatments, IEEE Trans Ultrason, Band 6, 1996, 43: 1063-1073

[Shin/97] Shin G S, Helfmann J, Die Temperaturabhängigkeit der Ultraschallgeschwindigkeit in biologischen Medien, Dissertation Fachbereich Physik, 1997, Berlin,

[Simon/97] Simon C, VanBaren P, Ebbini S, Quantitative analysis and applications of non-invasive temperature estimation using diagnostic ultrasound, IEEE International Ultrasonics Symposium, 1997,


[Seite 103↓]

[Simon/98] Simon C, VanBaren P, Ebbini E S, Two-dimensional temperature estimation using diagnostic ultrasound, Trans Ultrason, Band 4, 1998, 45: 1088-1099

[Simon/98a] Simon C, VanBaren P, Ebbini E S, Motion Compensation Algorithm for non-invasive two dimensional temperature estimation using diagnostic pulse-echo ultrasound, SPIE Bios: Surgical Applications of Energy, 1998,

[Stephanishen/71] Stephanishen P R, Transient radiation in a piston in an infinite planar baffle, J Acoust Soc Am, 1971, 49:

[Takata/77] Takata A N, Zanevald L, Richter W, Laser-induced thermal damage in skin, USAF School of Aerospace Med. Brooks AFB, Band TX. Rep, 1977, SAM-TR-77-38

[Taylor/89] Taylor K J W, Wells P N T, Tissue Characterization, Ultrasound Med Biol, 1989, 15: 421-428

[Vaezy/01] Vaezy S, Shi X, Martin R W, Chi E, Nelson P I, Baily M R, Crum L A, Real-Time Visualization of High Intensity Ultrasound Treatment using Ultrasound Imaging, Ultrason Med Biol, Band 1, 2001, 27: 33-42

[Vogl/95] Vogl TJ, MüllerP K, Hammerstingel R, Malignant liver tumors treated with MR imaging guided laser induced thermotherapy: Technique and prospective results, Radiology, 1995, 169: 257-265

[Vogl/97] Vogl TJ, Mack MG, Straub R, Roggan A, Felix R, Magnetic resonance imaging guided abdominal interventional radiology: laser induced thermotherapy of liver metastases, Endoscopy, 1997,

[Vogl/00] Vogl T J, Mack M G, Roggan A, Magnetresonanztomographisch gesteuerte laserinduzierte Thermotherapie von Lebermetastasen, Deutsches Ärzteblatt, Band 37, 2000, 97: 2386-2391

[Wells/69] Wells P N T, Physical Principles of Ultrasonic Imaging, 1969, London New York, Academic Pr,

[Wells/77] Wells P N T, Biomedical Ultrasonics, 1977, New York, Academic Press, 110-137


[Seite 104↓]

[Welch/84] Welch A J, The thermal response of laser irradiated tissue, IEEE Journal of Quantum Electronics, Band 12, 1984, 20: 1471-1481

[Whelan/99] Whelan W M, Wyman D R, Dynamic Modeling of Interstitial Laser Photocoagulation: Implications for Lesion Formation in Liver in Vivo, Lasers in Surgery and Medicine, 1999, 24: 202-208


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