In vivo determination of the absorption and scattering spectra of the human prostate during photodynamic therapy

A continuing challenge in photodynamic therapy is the accurate in vivo determination of the optical properties of the tissue being treated. We have developed a method for characterizing the absorption and scattering spectra of prostate tissue undergoing PDT treatment. Our current prostate treatment protocol involves interstitial illumination of the organ via cylindrical diffusing optical fibers (CDFs) inserted into the prostate through clear catheters. We employ one of these catheters to insert an isotropic white light point source into the prostate. An isotropic detection fiber connected to a spectrograph is inserted into a second catheter a known distance away. The detector is moved along the catheter by a computer-controlled step motor, acquiring diffuse light spectra at 2 mm intervals along its path. We model the fluence rate as a function of wavelength and distance along the detector’s path using an infinite medium diffusion theory model whose free parameters are the absorption coefficient μa at each wavelength and two variables A and b which characterize the reduced scattering spectrum of the form μ’s = Aλ-b. We analyze our spectroscopic data using a nonlinear fitting algorithm to determine A, b, and μa at each wavelength independently; no prior knowledge of the absorption spectrum or of the sample’s constituent absorbers is required. We have tested this method in tissue simulating phantoms composed of intralipid and the photosensitizer motexafin lutetium (MLu). The MLu absorption spectrum recovered from the phantoms agrees with that measured in clear solution, and μa at the MLu absorption peak varies linearly with concentration. The µ’s spectrum reported by the fit is in agreement with the known scattering coefficient of intralipid. We have applied this algorithm to spectroscopic data from human patients sensitized with MLu (2 mg kg-1) acquired before and after PDT. Before PDT, the absorption spectra we measure include the characteristic MLu absorption peak. Using our phantom data as a calibration, we have determined the pre-treatment MLu concentration to be approximately 2 to 8 mg kg-1. After PDT, the concentration is reduced to 1 to 2.5 mg kg-1, an indication of photobleaching induced by irradiation. In addition, absorption features corresponding to the oxygenated and deoxygenated forms of hemoglobin indicate a reduction in tissue oxygenation during treatment.

[1]  Jonathan L. Sessler,et al.  Texaphyrins: Synthesis and Development of a Novel Class of Therapeutic Agents , 2002 .

[2]  D. Delpy,et al.  Characterization of the near infrared absorption spectra of cytochrome aa3 and haemoglobin for the non-invasive monitoring of cerebral oxygenation. , 1988, Biochimica et biophysica acta.

[3]  M. Nichols,et al.  Design and testing of a white-light, steady-state diffuse reflectance spectrometer for determination of optical properties of highly scattering systems. , 1997, Applied optics.

[4]  Stanley B. Brown,et al.  Fluorescence Photobleaching of ALA‐induced Protoporphyrin IX during Photodynamic Therapy of Normal Hairless Mouse Skin: The Effect of Light Dose and Irradiance and the Resulting Biological Effect , 1998, Photochemistry and photobiology.

[5]  Thomas H. Foster,et al.  Noninvasive near-infrared hemoglobin spectroscopy for in vivo monitoring of tumor oxygenation and response to oxygen modifiers , 1997, Photonics West - Biomedical Optics.

[6]  Thomas H. Foster,et al.  Steady-state reflectance spectroscopy in the P 3 approximation , 2001 .

[7]  Thomas H. Foster,et al.  In Vivo mTHPC Photobleaching in Normal Rat Skin Exhibits Unique Irradiance-dependent Features¶ , 2002, Photochemistry and photobiology.

[8]  Thomas S. Mang,et al.  THE THEORY OF PHOTODYNAMIC THERAPY DOSIMETRY: CONSEQUENCES OF PHOTO‐DESTRUCTION OF SENSITIZER , 1987 .

[9]  Timothy C Zhu,et al.  In vivo reflectance measurement of optical properties, blood oxygenation and motexafin lutetium uptake in canine large bowels, kidneys and prostates. , 2002, Physics in medicine and biology.

[10]  W. M. Star Comparing the P3-approximation with diffusion theory and with Monte Carlo calculations of light propagation in a slab geometry , 1989, Other Conferences.

[11]  M G Nichols,et al.  Quantitative broadband near-infrared spectroscopy of tissue-simulating phantoms containing erythrocytes. , 1998, Physics in medicine and biology.

[12]  H. J. van Staveren,et al.  Light scattering in Intralipid-10% in the wavelength range of 400-1100 nm. , 1991, Applied optics.

[13]  J. Mourant,et al.  Predictions and measurements of scattering and absorption over broad wavelength ranges in tissue phantoms. , 1997, Applied optics.

[14]  B. Krammer,et al.  Vascular effects of photodynamic therapy. , 2001, Anticancer research.

[15]  B. Wilson,et al.  A diffusion theory model of spatially resolved, steady-state diffuse reflectance for the noninvasive determination of tissue optical properties in vivo. , 1992, Medical physics.

[16]  Hubert van den Bergh,et al.  In-vivo measurement of fluorescence bleaching of meso-tetra hydroxy phenyl chlorin (mTHPC) in the esophagus and the oral cavity , 1995, European Conference on Biomedical Optics.

[17]  E. Hull,et al.  Porphyrin Bleaching and PDT-induced Spectral Changes are Irradiance Dependent in ALA-sensitized Normal Rat Skin In Vivo¶ , 2001, Photochemistry and photobiology.

[18]  D. M. Burns,et al.  THE MEASUREMENT OF DIHEMATOPORPHYRIN ETHER CONCENTRATION IN TISSUE BY REFLECTANCE SPECTROPHOTOMETRY , 1987, Photochemistry and photobiology.

[19]  J. Sessler,et al.  Lutetium Texaphyrin (PCI‐0123): A Near‐Infrared, Water‐Soluble Photosensitizer , 1996, Photochemistry and photobiology.