Abstract
Tissue mimicking phantom materials with thermal and dielectric equivalence are vital for the development of microwave diagnostics and treatment. The current phantoms representing fat tissue are challenged by mechanical integrity at relevant temperatures coupled with complex production protocols. We have employed two types of nanocellulose (cellulose nanocrystals and oxidized cellulose nanocrystals) as reinforcement in gelatin stabilized emulsions for mimicking fat tissue. The nanocellulose-gelatin stabilized emulsions were evaluated for their dielectric properties, the moduli-temperature dependence using small deformation rheology, stress-strain behavior using large deformation, and their compliance to quality assurance guidelines for superficial hyperthermia. All emulsions had low permittivity and conductivity within the lower microwave frequency band, accompanied by fat equivalent thermal properties. Small deformation rheology showed reduced temperature dependence of the moduli upon addition of nanocellulose, independent of type. The cellulose nanocrystals gelatin reinforced emulsion complied with the quality assurance guidelines. Hence, we demonstrate that the addition of cellulose nanocrystals to gelatin stabilized emulsions has the potential to be used as fat phantoms for the development of microwave diagnostics and treatment.
Highlights
Microwave applications for medical diagnostics and treatment are emerging in today’s health care systems
We have demonstrated that nanocellulose reinforcement increased the thermal stability of gelatin hydrogels and can be used to reinforce fat-mimicking phantoms for microwave application
CNCgelatin, and dialdehyde CNCs through oxidation (DAC)-gelatin reinforced emulsion all fulfill the requirements of phantom dielectric properties
Summary
Microwave applications for medical diagnostics and treatment are emerging in today’s health care systems. The high contrast between dielectric properties of healthy and malignant tissues compensate for mediocre spatial resolution so that the microwave systems can serve as a fast decision tool for diagnostics of stroke and traumas [1, 2], detection of breast cancer [3,4,5,6] or localization of epileptic brain activity [7] Another application of microwaves is hyperthermia cancer treatment, in which the tumor temperature is elevated to therapeutic levels to kill the tumor cells and/or making them vulnerable to other treatment modalities, such as radiotherapy and chemotherapy [8,9,10,11]. Hyperthermia phantoms have an additional demand of thermal equivalence to enable accurate measurements of power and temperature deposition patterns of the applicators [17, 18]
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