ABSTRACT
The parathyroid glands are small and often similar to lymph nodes, fat, and thyroid tissue. These glands are difficult to identify during surgery and a biopsy of the parathyroid for identification can lead to damage of the gland. The use of static and time-resolved fluorescence techniques to detect biochemical composition and tissue structure alterations could help to develop a portable, minimally invasive, and nondestructive method to assist medical evaluation of parathyroid tissues. In this study, we investigated 10 human parathyroid samples by absorbance, fluorescence, excitation, and time-resolved fluorescence measurements. Moreover, we compared the results of time-resolved fluorescence measurements with 59 samples of thyroid tissues. The fluorescence lifetimes with emission at 340 nm were 1.09 ± 0.10 and 4.46 ± 0.06 ns for healthy tissue, 1.01 ± 0.25 and 4.39 ± 0.36 ns for benign lesions, and 0.67 ± 0.36 and 3.92 ± 0.72 ns for malignant lesions. The lifetimes for benign and malignant lesions were significantly different, as attested by the analysis of variance with confidence levels higher than 87%. For each class of samples (healthy, benign, and malignant) we perceived statistical differences between the thyroid and parathyroid tissue, independently. After further investigations, fluorescence methods could become a tool to identify normal and pathological parathyroid tissues and distinguish thyroid from parathyroid tissues.
ABSTRACT
Fine-needle aspiration cytology is the standard technique to diagnose thyroid pathologies. However, this method has a high percentage of inconclusive and false-negative results for benign and malignant lesions. Hence, it is important to search for a new method to assist medical evaluation during these surgical procedures. The use of time-resolved fluorescence techniques to detect biochemical composition and tissue structure alterations could help to develop a portable, minimally invasive, and non-destructive method to assist medical evaluation. In this study, we investigated 17 human thyroid samples by absorbance, fluorescence, excitation, and time-resolved fluorescence measurements. This initial investigation has demonstrated that thyroid fluorescence originates from many endogenous fluorophores and culminates in several bands. The fluorescence lifetimes of benign and malignant lesions were significantly different, as attested by analysis of variance using Tukey test with individual confidence level of 98.06%. Our results suggest that fluorescence lifetimes of benign and malignant lesions can potentially assist diagnosis. After further investigations, fluorescence methods could become a tool for the surgeon to identify differences between normal and pathological thyroid tissues.
