Whole-body hyperthermia: a review of theory, design and application

Vertrees, Roger A.; Leeth, Angela; Girouard, Mark K; Roach, John D; Zwischenberger, Joseph B.

doi:10.1191/0267659102pf588oa

Cited by 42 publications

(26 citation statements)

References 78 publications

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“…Unfortunately, "extreme" whole body hyperthermia (.41.5°C), which elevates core temperatures to the level where direct thermal toxicity is observed, can cause severe side effects, which may limit its usefulness. [4][5][6][7][8] Fever-level whole body hyperthermia (∼39°C-41°C) can mitigate many of these side effects and has potential to be an effective cancer treatment, but this lower heat level is thought, primarily, to stimulate the immune system and the benefits of direct thermal toxicity are reduced. 9,10 Generating localized hyperthermia at the cancer site could alleviate many of the side effects associated with whole body hyperthermia while still taking advantage of the thermal susceptibility of tumors.…”

Section: Introductionmentioning

confidence: 99%

Cell-delivered magnetic nanoparticles caused hyperthermia-mediated increased survival in a murine pancreatic cancer model

Basel¹,

Balivada²,

Wang³

et al. 2012

IJN

114

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Using magnetic nanoparticles to absorb alternating magnetic field energy as a method of generating localized hyperthermia has been shown to be a potential cancer treatment. This report demonstrates a system that uses tumor homing cells to actively carry iron/iron oxide nanoparticles into tumor tissue for alternating magnetic field treatment. Paramagnetic iron/ iron oxide nanoparticles were synthesized and loaded into RAW264.7 cells (mouse monocyte/ macrophage-like cells), which have been shown to be tumor homing cells. A murine model of disseminated peritoneal pancreatic cancer was then generated by intraperitoneal injection of Pan02 cells. After tumor development, monocyte/macrophage-like cells loaded with iron/ iron oxide nanoparticles were injected intraperitoneally and allowed to migrate into the tumor. Three days after injection, mice were exposed to an alternating magnetic field for 20 minutes to cause the cell-delivered nanoparticles to generate heat. This treatment regimen was repeated three times. A survival study demonstrated that this system can significantly increase survival in a murine pancreatic cancer model, with an average post-tumor insertion life expectancy increase of 31%. This system has the potential to become a useful method for specifically and actively delivering nanoparticles for local hyperthermia treatment of cancer.

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Section: Introductionmentioning

confidence: 99%

Cell-delivered magnetic nanoparticles caused hyperthermia-mediated increased survival in a murine pancreatic cancer model

Basel¹,

Balivada²,

Wang³

et al. 2012

IJN

114

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“…After the introduction of blood circulation into the heat exchanger, it is easy to control and monitor the temperature [87]. The ongoing Phase I study in advanced non-small-cell lung cancer patients approved by the US FDA has shown its safety and effectiveness [88][89][90][91][92][93]. Several therapeutic effective strategies of heat in combination with other antineoplastics have been developed in this platform as shown in Figure 7a.…”

Section: Extracorporeal Circuitmentioning

confidence: 97%

Current devices for high-performance whole-body hyperthermia therapy

Jia

Liu

2010

Expert Review of Medical Devices

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For late-stage cancer, whole-body hyperthermia (WBH) is highly regarded by physicians as a promising alternative to conventional therapies. Although WBH is still under scrutiny due to potential toxicity, its benefits are incomparable, as diversified devices and very promising treatment protocols in this area are advanced into Phase II and III clinical trials. Following the introduction of the WBH principle, this paper comprehensively reviews the state-of-art high-performance WBH devices based on the heat induction mechanisms - radiation, convection and conduction. Through analyzing each category's physical principle and heat-induction property, the advantages and disadvantages of the devices are evaluated. Technical strategies and critical scientific issues are summarized. For future developments, research directions worth pursuing are presented in this article.

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“…Actually, the rich network of vessels absorbs bigger proportion of heat than compartment average if the equal amount of heat is imposed from outside. The unexpected systemic thermal responses reported during clinical practice in a regional hyperthermia [27,28] indicate the need of both description of remote temperature responses and the utilization of these effects. Given that 20 W heat is irradiated from skin surface, the heat absorbed by blood will be 6 W for systemic [15], the same as the compartment calculation.…”

Section: Systemic Thermal Response By Heating In Hands and Feetmentioning

confidence: 99%