We report on high-temperature sensing measurements using a tubular-lattice hollow-core photonic crystal fiber (HCPCF) displaying a microstructure formed of eight 2.4- μ m-thick cladding tubes. The larger thickness of our fiber’s cladding tubes compared to other hollow fibers operating in the visible and infrared ranges entails multiple narrow transmission bands in its transmission spectrum (six bands in the spectral range between 400 and 950 nm) and benefits the realization of the temperature sensing measurements. The principle of operation of our device is based on the thermo-optic effect and thermal expansion-induced spectral shifts of the fiber transmission bands due to temperature variations. To study the sensor operation, we monitored the fiber transmission bands’ spectral positions from room temperature to 1085 ∘ C in both ramp-up and ramp-down scenarios. Additionally, we investigated the optimization opportunities by assessing an analytical model describing the fiber transmission characteristics and discussed the alternatives for enhancing the sensor performance. Moreover, our fiber characterization experiments revealed a consistent confinement loss (CL) trend aligned with the scaling laws in tubular-lattice hollow-core fibers. We thus understand that the results presented in this article highlight a relevant path for the development of temperature sensors based on microstructured hollow-core optical fibers endowed with thick cladding tubes