New experimental model for single liver lobe hyperthermia in small animals using non-directional microwaves

Our aim was to develop a new experimental model for in vivo hyperthermia using non-directional microwaves, applicable to small experimental animals. We present an affordable approach for targeted microwave heat delivery to an isolated liver lobe in rat, which allows rapid, precise and stable tissue...

Full description

Saved in:
Bibliographic Details
Published in:PloS one 2017-09, Vol.12 (9), p.e0184810-e0184810
Main Authors: Tudorancea, Ionuț, Porumb, Vlad, Trandabăţ, Alexandru, Neaga, Decebal, Tamba, Bogdan, Iliescu, Radu, Dimofte, Gabriel M
Format: Article
Language:English
Subjects:
Animal models
Animals
Antennas
Biology and Life Sciences
Body Temperature
Cancer therapies
Chemotherapy
Control equipment
Control methods
Electrical Equipment and Supplies
Engineering and Technology
Equipment Design
Experiments
Fever
Fever - physiopathology
Gangrene
Heat
Heating
Hot Temperature
Hyperthermia
Hyperthermia, Induced - instrumentation
In vivo methods and tests
Linear Models
Liver
Liver - physiology
Liver - physiopathology
Liver Diseases - physiopathology
Liver Diseases - therapy
Male
Medicine
Medicine and Health Sciences
Methods
Microwave radiation
Microwaves
Models, Animal
Oncology
Ovens & stoves
Overheating
Pharmacy
Physical Sciences
Power supply
Radiation
Rats
Rats, Wistar
Surgery
Temperature
Temperature control
Temperature effects
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Our aim was to develop a new experimental model for in vivo hyperthermia using non-directional microwaves, applicable to small experimental animals. We present an affordable approach for targeted microwave heat delivery to an isolated liver lobe in rat, which allows rapid, precise and stable tissue temperature control. A new experimental model is proposed. We used a commercial available magnetron generating 2450 MHz, with 4.4V and 14A in the filament and 4500V anodic voltage. Modifications were required in order to adjust tissue heating such as to prevent overheating and to allow for fine adjustments according to real-time target temperature. The heating is controlled using a virtual instrument application implemented in LabView® and responds to 0.1° C variations in the target. Ten healthy adult male Wistar rats, weighing 250-270 g were used in this study. The middle liver lobe was the target for controlled heating, while the rest of the living animal was protected. In vivo microwave delivery using our experimental setting is safe for the animals. Target tissue temperature rises from 30°C to 40°C with 3.375°C / second (R2 = 0.9551), while the increment is lower it the next two intervals (40-42°C and 42-44°C) with 0.291°C/ s (R2 = 0.9337) and 0.136°C/ s (R2 = 0.7894) respectively, when testing in sequences. After reaching the desired temperature, controlled microwave delivery insures a very stable temperature during the experiments. We have developed an inexpensive and easy to manufacture system for targeted hyperthermia using non-directional microwave radiation. This system allows for fine and stable temperature adjustments within the target tissue and is ideal for experimental models testing below or above threshold hyperthermia.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0184810