Fluorescent nanothermometers can probe changes in local temperature in living cells and in
vivo and reveal fundamental insights into biological properties. This field has attracted …

Conventional thermal biology has elucidated the physiological function of temperature
homeostasis through spontaneous thermogenesis and responses to variations in …

The high population growth rate, massive animal food consumption, fast economic progress,
and limited food resources could lead to a food crisis in the future. There is a huge …

Temperature is an important factor in the process of life, as thermal energy transfer
participates in all biological events in organisms. Due to technical limitations, there is still a …

Vibrational energy exchange between various degrees of freedom is critical to barrier-
crossing processes in proteins. Hemeproteins are well suited for studying vibrational energy …

Cellular metabolic heat (ΔP M) is produced from intracellular reactions, carrying information
about particular processes thus indicating the status of organisms. ΔP M originating from a …

Heat generation or consumption is required for all biological processes. Microcalorimetry is
an ultrasensitive method to measure heat change for various applications. In this paper, we …

To understand the mechanism of intracellular thermal transport, thermal properties must be
elucidated, particularly thermal conductivity and specific heat capacity. However, these …

The discipline of microphysiometry emerged at the end of the 1980s and has been
progressing towards today's organs on chips and microphysiological systems approaches …

Temperature is a fundamental physical parameter that influences biological processes in
living cells. Hence, intracellular temperature map** can be used to derive useful …