OBJECTIVE: The aim of this study was to measure spontaneous photon emission (SPE) and delayed luminescence (DL) from various human cancer tissues. MATERIALS AND METHODS: A photomultiplier tube attached to a dark chamber was used for the detection of ultraweak photon emission from cancer tissues in the chamber. The samples were illuminated with a 150 W metal halide lamp for the measurement of delayed luminescence. Frozen tissues were provided by the hospitals and preserved in saline solution in a CO2 incubator for 1 hour before starting the measurement of spontaneous photon emission. We successively measured the afterglows from the samples after 30-second irradiation of the lamp. The samples were divided into two groups: tumor tissues and normal tissues around tumor tissues. We presented experimental data and interpreted their characteristic patterns of spontaneous photon emission and delayed luminescence. RESULTS: Mean values of spontaneous photon emissions from the normal tissues and the tumor tissues were measured with the standard errors of the mean as 625 +/- 419 counts/minute/cm2 (n = 6) and 982 +/- 513 counts/minute/cm2 (n = 14), respectively. Peak values of the intensity of delayed luminescence from normal and cancerous tissues were 63 +/- 20 counts/ms (n = 6) and 48 +/- 12 counts/ms (n = 14). CONCLUSIONS: The intensity of spontaneous photon emissions from cancer tissues were mostly discriminated from those of normal tissues, and their delayed luminescent properties were investigated.
OBJECTIVE: The aim of this study was to measure spontaneous photon emission (SPE) and delayed luminescence (DL) from various humancancer tissues. MATERIALS AND METHODS: A photomultiplier tube attached to a dark chamber was used for the detection of ultraweak photon emission from cancer tissues in the chamber. The samples were illuminated with a 150 W metalhalide lamp for the measurement of delayed luminescence. Frozen tissues were provided by the hospitals and preserved in saline solution in a CO2 incubator for 1 hour before starting the measurement of spontaneous photon emission. We successively measured the afterglows from the samples after 30-second irradiation of the lamp. The samples were divided into two groups: tumor tissues and normal tissues around tumor tissues. We presented experimental data and interpreted their characteristic patterns of spontaneous photon emission and delayed luminescence. RESULTS: Mean values of spontaneous photon emissions from the normal tissues and the tumor tissues were measured with the standard errors of the mean as 625 +/- 419 counts/minute/cm2 (n = 6) and 982 +/- 513 counts/minute/cm2 (n = 14), respectively. Peak values of the intensity of delayed luminescence from normal and cancerous tissues were 63 +/- 20 counts/ms (n = 6) and 48 +/- 12 counts/ms (n = 14). CONCLUSIONS: The intensity of spontaneous photon emissions from cancer tissues were mostly discriminated from those of normal tissues, and their delayed luminescent properties were investigated.