Two-photon excited fluorescence lifetime imaging and spectroscopy of melanins in vitro and in vivo

Abstract. Changes in the amounts of cellular eumelanin and pheomelanin have been associated with carcinogenesis. The goal of this work is to develop methods based on two-photon-excited-fluorescence (TPEF) for measuring relative concentrations of these compounds. We acquire TPEF emission spectra (λex=1000  nm) of melanin in vitro from melanoma cells, hair specimens, and in vivo from healthy volunteers. We find that the pheomelanin emission peaks at approximately 615 to 625 nm and eumelanin exhibits a broad maximum at 640 to 680 nm. Based on these data we define an optical melanin index (OMI) as the ratio of fluorescence intensities at 645 and 615 nm. The measured OMI for the MNT-1 melanoma cell line is 1.6±0.22 while the Mc1R gene knockdown lines MNT-46 and MNT-62 show substantially greater pheomelanin production (OMI=0.5±0.05 and 0.17±0.03, respectively). The measured values are in good agreement with chemistry-based melanin extraction methods. In order to better separate melanin fluorescence from other intrinsic fluorophores, we perform fluorescence lifetime imaging microscopy of in vitro specimens. The relative concentrations of keratin, eumelanin, and pheomelanin components are resolved using a phasor approach for analyzing lifetime data. Our results suggest that a noninvasive TPEF index based on spectra and lifetime could potentially be used for rapid melanin ratio characterization both in vitro and in vivo.

[1]  Warren S. Warren,et al.  In vivo and ex vivo epi-mode pump-probe imaging of melanin and microvasculature , 2011, Biomedical optics express.

[2]  Shosuke Ito,et al.  Cutaneous photobiology. The melanocyte vs. the sun: who will win the final round? , 2003, Pigment cell research.

[3]  K. Wakamatsu,et al.  An improved modification of permanganate oxidation of eumelanin that gives a constant yield of pyrrole-2,3,5-tricarboxylic acid. , 1994, Pigment cell research.

[4]  Shosuke Ito,et al.  Quantitative measures of the effect of the melanocortin 1 receptor on human pigmentary status. , 2004, The Journal of investigative dermatology.

[5]  K. Wakamatsu,et al.  Chemical degradation of melanins: application to identification of dopamine-melanin. , 1998, Pigment cell research.

[6]  G J Hill,et al.  UVA, pheomelanin and the carcinogenesis of melanoma. , 2000, Pigment cell research.

[7]  Klaus Hoffmann,et al.  Fluorescence Studies of Melanin by Stepwise Two-Photon Femtosecond Laser Excitation , 2000, Journal of Fluorescence.

[8]  T. Andresen,et al.  Molecular basis of phospholipase A2 activity toward phospholipids with sn-1 substitutions. , 2008, Biophysical journal.

[9]  Matthias Scholz,et al.  The stepwise two‐photon excited melanin fluorescence is a unique diagnostic tool for the detection of malignant transformation in melanocytes , 2011, Pigment cell & melanoma research.

[10]  K. Wakamatsu,et al.  Advanced chemical methods in melanin determination. , 2002, Pigment cell research.

[11]  P Altmeyer,et al.  Selective femtosecond pulse-excitation of melanin fluorescence in tissue. , 2001, The Journal of investigative dermatology.

[12]  Shosuke Ito,et al.  Human melanocortin 1 receptor variants, receptor function and melanocyte response to UV radiation. , 2002, Journal of cell science.

[13]  Goran Stankovic,et al.  Uncovering of melanin fluorescence in human skin tissue , 2007, European Conference on Biomedical Optics.

[14]  Renato Marchesini,et al.  In vivo characterization of melanin in melanocytic lesions: spectroscopic study on 1671 pigmented skin lesions. , 2009, Journal of biomedical optics.

[15]  S. Ito,et al.  Microanalysis of eumelanin and pheomelanin in hair and melanomas by chemical degradation and liquid chromatography. , 1985, Analytical biochemistry.

[16]  Warren S Warren,et al.  Pump-Probe Imaging Differentiates Melanoma from Melanocytic Nevi , 2011, Science Translational Medicine.

[17]  Kari Stefansson,et al.  ASIP and TYR pigmentation variants associate with cutaneous melanoma and basal cell carcinoma , 2008, Nature Genetics.

[18]  E. Land,et al.  Interaction of radicals from water radiolysis with melanin. , 1986, Biochimica et biophysica acta.

[19]  Karsten König,et al.  Sensitivity and specificity of multiphoton laser tomography for in vivo and ex vivo diagnosis of malignant melanoma. , 2009, The Journal of investigative dermatology.

[20]  Efthimios Kaxiras,et al.  Melanin absorption spectroscopy: new method for noninvasive skin investigation and melanoma detection. , 2008, Journal of biomedical optics.

[21]  James Knittel,et al.  The Melanocortin 1 Receptor and the UV Response of Human Melanocytes—A Shift in Paradigm † , 2008, Photochemistry and photobiology.

[22]  K. Jimbow,et al.  Current update and trends in melanin pigmentation and melanin biology. , 1995, The Keio journal of medicine.

[23]  E. Gratton,et al.  Phasor approach to fluorescence lifetime microscopy distinguishes different metabolic states of germ cells in a live tissue , 2011, Proceedings of the National Academy of Sciences.

[24]  Rachel M Haywood,et al.  Comparable Photoreactivity of Hair Melanosomes, Eu‐ and Pheomelanins at Low Concentrations: Low Melanin a Risk Factor for UVA Damage and Melanoma? † , 2008, Photochemistry and photobiology.

[25]  Bruce Tromberg,et al.  Photodynamic therapy on keloid fibroblasts in tissue‐engineered keratinocyte‐fibroblast co‐culture , 2005, Lasers in surgery and medicine.

[26]  Enrico Gratton,et al.  A novel fluorescence lifetime imaging system that optimizes photon efficiency , 2008, Microscopy research and technique.

[27]  E. Gratton,et al.  The phasor approach to fluorescence lifetime imaging analysis. , 2008, Biophysical journal.

[28]  R. Sturm Skin colour and skin cancer - MC1R, the genetic link. , 2002, Melanoma research.