A recent study undertaken at Rovira i Virgili University in Tarragona, Spain, reveals that biolabelling through luminescence thermometry has the potential to detect cancer cells at an early stage of development, just by monitoring the temperature rise in the body, due to accelerated metabolic activities in abnormal cells.
The Linkam THMS600 stage was used by researchers at the university to study the fluorescence of the nanoparticles that are produced. They used UV-Vis-NIR spectroscopy to characterise the nanomaterial’s emission spectra as a function of temperature, which then allowed them to use the catalogued emissions as in vitro luminescent nanothermometers. The observation of temperature-dependent luminescent particles for use as nanothermometers is made possible by the easy manipulation and chamber control provided by the THMS600, allowing for precise temperature and environmental control with the ability to image the sample through a wide range of microscopic and spectroscopic techniques.
Duncan Stacey at Linkam comments: “Our stages are perfectly suited for the analysis of temperature-sensitive materials such as these luminescent particles. They can be used in a range of applications, from biological samples to photovoltaics, where precise temperature accuracy and stability are required as well as the ability to image the sample through microscopy or spectroscopy. This is the case for the research undertaken at Rovira i Virgili University where a wide temperature range and pinpoint accuracy were necessary. Their work provides essential insight into the behaviour of temperature-responsive particles for cancer detection, and we are pleased to help enable such research.”
The researchers placed the sample on top of a boron nitride disc to aid with the uniform and fast distribution of temperature, ensuring that the entire sample is maintained at the same heat. Temperature stability and control is a critical aspect in the calibration of the development of the luminescent nanothermometers, hence the use of Linkam’s precision thermal control stages.
Joan Josep Carvajal Marti, Vice-dean of the Faculty of Chemistry at Rovira i Virgili University, Spain comments: “The use of the stage allowed us, among other things, to develop luminescent thermometers operating in the different optical biological windows located in the near infrared part of the electromagnetic spectrum. This is where biological tissues are more transparent to the light, attaining deeper penetration depths which would allow the future treatment of diseases, such as cancer, through laparoscopic techniques.
“We have also been able to develop thermochromic thermometers, in which the colour of the emission changes in accordance with the temperature, and that can be used as naked eye indicators as to whether industrial processes are progressing correctly or not.”