A.-G. Pawlowski scite author profile

A magnetic hyperthermia cancer treatment strategy that does not operate by means of conventional heating mechanisms is presented. The proposed approach consists of injecting a gel with homogeneously distributed magnetic nanowires into a tumor. Upon the application of a low-frequency rotating or circularly polarized magnetic field, nanowires spin around their center of viscous drag due to torque generated by shape anisotropy. As a result of external rotational forcing and fluid friction in the nanoparticle's boundary layer, heating occurs. The nanowire dynamics is theoretically and experimentally investigated, and different feasibility proofs of the principle by physical modeling, which adhere to medical guidelines, are presented. The magnetic nanorotors exhibit rotations and oscillations with quite a steady center of gravity, which proves an immobile behavior and guarantees a time-independent homogeneity of the spatial particle distribution in the tumor. Furthermore, a fluid dynamic and thermodynamic heating model is briefly introduced. This model is a generalization of Penne's model that for this method reveals theoretic heating rates that are sufficiently high, and fits well into medical limits defined by present standards.

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Elastomer mask for powder blasting microfabrication

Sayah

Parashar

Pawlowski

et al. 2005

Sensors and Actuators A: Physical

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Powder blasting patterning technology for microfabrication of complex suspended structures in glass

Pawlowski

Belloy

Sayah

et al. 2003

Microelectronic Engineering

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Accurate masking technology for high-resolution powder blasting

Pawlowski

Sayah

Gijs

2005

J. Micromech. Microeng.

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We have combined eroding 10 µm diameter Al 2 O 3 particles with a new masking technology to realize the smallest and most accurate possible structures by powder blasting. Our masking technology is based on the sequential combination of two polymers:(i) the brittle epoxy resin SU8 for its photosensitivity and (ii) the elastic and thermocurable polydimethylsiloxane for its large erosion resistance. We have micropatterned various types of structures with a minimum width of 20 µm for test structures with an aspect ratio of 1, and 50 µm for test structures with an aspect ratio of 2.

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A.-G. Pawlowski

Microfabrication of high-aspect ratio and complex monolithic structures in glass

Hyperthermia with rotating magnetic nanowires inducing heat into tumor by fluid friction

Elastomer mask for powder blasting microfabrication

Powder blasting patterning technology for microfabrication of complex suspended structures in glass

Accurate masking technology for high-resolution powder blasting

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