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Your search keyword '"Ralph Pflanzer"' showing total 3 results
Start Over Author "Ralph Pflanzer" Topic biomedical engineering
3 results on '"Ralph Pflanzer"'

1. Scanning acoustic microscopy—A novel noninvasive method to determine tumor interstitial fluid pressure in a xenograft tumor model

Author

Anowarul Habib, August Bernd, Amit Shelke, Robert Sader, Jürgen Bereiter-Hahn, Stefan Kippenberger, Roland Kaufmann, Ralph Pflanzer, and Matthias Hofmann

Subjects
0301 basic medicine, Cancer Research, Pathology, medicine.medical_specialty, business.industry, VDP::Medical disciplines: 700::Clinical medical disciplines: 750::Oncology: 762, Hydrostatic pressure, Scanning Acoustic Microscopy, Interstitial fluid pressure, lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens, lcsh:RC254-282, VDP::Medisinske Fag: 700::Klinisk medisinske fag: 750::Onkologi: 762, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Oncology, Signal strength, 030220 oncology & carcinogenesis, medicine, Ultrasonic sensor, business, Tumor xenograft, Biomedical engineering
Abstract

This is an open access article under the CC BY-NC-ND license. This article is also available via DOI:10.1016/j.tranon.2016.03.009 Elevated tumor interstitial fluid pressure (TIFP) is a prominent feature of solid tumors and hampers the transmigration of therapeutic macromolecules, for example, large monoclonal antibodies, from tumor-supplying vessels into the tumor interstitium. TIFP values of up to 40 mm Hg have been measured in experimental solid tumors using two conventional invasive techniques: the wick-in-needle and the micropuncture technique. We propose a novel noninvasive method of determining TIFP via ultrasonic investigation with scanning acoustic microscopy at 30-MHz frequency. In our experimental setup, we observed for the impedance fluctuations in the outer tumor hull of A431-vulva carcinoma–derived tumor xenograft mice. The gain dependence of signal strength was quantified, and the relaxation of tissue was calibrated with simultaneous hydrostatic pressure measurements. Signal patterns from the acoustical images were translated into TIFP curves, and a putative saturation effect was found for tumor pressures larger than 3 mm Hg. This is the first noninvasive approach to determine TIFP values in tumors. This technique can provide a potentially promising noninvasive assessment of TIFP and, therefore, can be used to determine the TIFP before treatment approach as well to measure therapeutic efficacy highlighted by lowered TFP values.

Published
2016

2. Ultrasonic Quantification of Tumor Interstitial Fluid Pressure Through Scanning Acoustic Microscopy

Author

Ralph Pflanzer, Jürgen Bereiter-Hahn, Amit Shelke, and Matthias Hofmann

Subjects
In situ, Tumor microenvironment, Scanning Acoustic Microscopy, Acoustic microscopy, Ultrasonic sensor, Anatomy, Interstitial fluid pressure, Acoustic impedance, Tumor xenograft, Biomedical engineering
Abstract

High tumor interstitial fluid pressure (TIFP) is characteristic of solid tumors. Elevated TIFP inhibits the assimilation of macromolecular therapeutics in tumor tissue as well as it induces mechanical strain triggering cell proliferation in solid tumors. Common solid epithelial tumors of A431 carcinoma cells exhibit a TIFP of about 10–15 mmHg measured conventionally through wick-in-needle technique. A new scheme to determine topography and acoustic impedance in solid tumor is proposed through scanning acoustic microscopy. The change in amplitude and time of flight at 30 MHz acoustic signal is used to quantify the growth pattern and to calibrate elevation of TIFP. The wide variability of amplitude and frequency in topographic sections indicate discrete envelopes of individual tumors with localized TIFP. Further investigations in applying this non-invasive method as a means of measuring TIFP in subcutaneous mice xenograft tumors in situ could also enhance understanding of tumor microenvironment and vessel architecture in living tissue.

Published
2012

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