Development of a rat capnoperitoneum phantom to study drug aerosol deposition in the context of anticancer research on peritoneal carcinomatosis

Daniel Göhler,Jonathan R Buggisch,Urs Giger-Pabst,Franz Lohse,Stephan Große,Julien Sobilo,Antje Geldner,Clemens Felsmann,Andreas Rudolph,Alain Le Pape,Ralf Gritzki,Michael Stintz

doi:10.1038/s41598-021-01332-0

Abstract

Pressurized Intraperitoneal Aerosol Chemotherapy (PIPAC) is a promising approach with a high optimization potential for the treatment of peritoneal carcinomatosis. To study the efficacy of PIPAC and drugs, first rodent cancer models were developed. But inefficient drug aerosol supply and knowledge gaps concerning spatial drug distribution can limit the results based on such models. To study drug aerosol supply/deposition, computed tomography scans of a rat capnoperitoneum were used to deduce a virtual and a physical phantom of the rat capnoperitoneum (RCP). RCP qualification was performed for a specific PIPAC method, where the capnoperitoneum is continuously purged by the drug aerosol. In this context, also in-silico analyses by computational fluid dynamic modelling were conducted on the virtual RCP. The physical RCP was used for ex-vivo granulometric analyses concerning drug deposition. Results of RCP qualification show that aerosol deposition in a continuous purged rat capnoperitoneum depends strongly on the position of the inlet and outlet port. Moreover, it could be shown that the droplet size and charge condition of the drug aerosol define the deposition efficiency. In summary, the developed virtual and physical RCP enables detailed in-silico and ex-vivo analyses on drug supply/deposition in rodents.

Highlights

Mindless of conventional or modified pressurized intraperitoneal chemotherapy (PIPAC) approaches, there are a lot of knowledge gaps concerning drug aerosol supply, propagation and deposition, which can be analysed without the use of animals or humans by means of adequate animal or human replacement models
Mindless of conventional PIPAC or alternative procedures, there are a lot of knowledge gaps concerning drug aerosol supply, drug aerosol propagation and particle deposition
Highly resolved CT-images of the capnoperitoneum of a 275 g RNU rat were used to deduce at first a virtual rat capnoperitoneum phantom (RCP) with a capnoperitoneal volume of 146 mL

Summary

Introduction

We started to develop a static rat capnoperitoneum phantom (RCP) in virtual and physical form to study drug aerosol supply and deposition. Different scenarios for drug aerosol supply were chosen to (i) characterise the performance of the virtual and the physical phantom and (ii) to study the impact of different measures (i.e., flow rates, purging direction, aerosol charge condition) on flow conditions and aerosol deposition.

Results

Conclusion