Quantitative Photothermal Characterization with Bioprinted 3D Complex Tissue Constructs for Early‐Stage Breast Cancer Therapy Using Gold Nanorods

Plasmonic photothermal therapy (PPTT) using gold nanoparticles (AuNPs) has shown great potential for use in selective tumor treatment, because the AuNPs can generate destructive heat preferentially upon irradiation. However, PPTT using AuNPs has not been added to practice, owing to insufficient heating methods and tissue temperature measurement techniques, leading to unreliable and inaccurate treatments. Because the photothermal properties of AuNPs vary with laser power, particle optical density, and tissue depth, the accurate prediction of heat generation is indispensable for clinical treatment. In this report, bioprinted 3D complex tissue constructs comprising processed gel obtained from porcine skin and human decellularized adipose tissue are presented for characterization of the photothermal properties of gold nanorods (AuNRs) having an aspect ratio of 3.7 irradiated by a near‐infrared laser. Moreover, an analytical function is suggested for achieving PPTT that can cause thermal damage selectively on early‐stage human breast cancer by regulating the heat generation of the AuNRs in the tissue. The accurate prediction of heat generation on tumor tissue is indispensable for clinical plasmonic photothermal therapy (PPTT). An analytical function to predict the temperature variation is suggested by analyzing heat generation using various 3D tissue construct and computational biophysics analysis. Also, selective thermal damage on early‐stage human breast cancer is confirmed using bioprinted 3D complex tissue constructs.