Abstract
BackgroundOptimization of intraperitoneal drug delivery systems requires functional models. We proposed the Inverted Bovine Urinary Bladder Model (IBUB), but IBUB does not allow repeated measurements over time and there is a significant biological variability between organs.MethodsA further development of IBUB is presented, based on the physical principle of communicating vessels. Fresh bovine bladders were inverted so that the peritoneum lines up the inner surface. The IBUB and a second vessel were then interconnected under the same CO2 pressure and placed on two scales. The therapeutic solution (Doxorubicin 2.7 mg and Cisplatin 13.5 mg) was delivered via an aerosolizer. All experiments were in triplicate and blinded to the origin of samples, measurements in a GLP-certified laboratory.ResultsThe enhanced IBUB (eIBUB) model allows measurements of tissue drug concentration, depth of tissue penetration and spatial distribution. The homogeneous morphology of the peritoneum enables standardized, multiple tissue sampling. eIBUB minimizes biological variability between different bladders and eliminates the bias caused by the liquid collecting at the bottom of the model. Concentration of doxorubicin in the eIBUB (mean ± STDV: 18.5 ± 22.6 ng/mg) were comparable to clinical peritoneal biopsies (19.2 ± 38.6 ng/mg), as was depth of drug penetration (eIBUB: mean (min-max) 433 (381–486) µm, clinical ~ 500 µm).ConclusionsThe eIBUB model is a simple and powerful ex vivo model for optimizing intraperitoneal drug delivery and represents an attractive alternative to animal models. Results obtained are similar to those obtained in the human patient.
Highlights
Peritoneal metastasis of gastrointestinal and gynecological origin are frequent with an estimated worldwide incidence of 1,000,000 new cases/year [1, 2]
We have described an innovative model for optimizing homogeneity of drug delivery using therapeutic pressurized aerosols, the Inverted Bovine Urinary Bladder Model (IBUB) model [20]
Animals are used in most preclinical studies on IP drug delivery [17, 21,22,23,24,25,26]. These animal models have been applied for improving depth of tissue penetration, homogeneity of distribution and to optimize contact time between the therapeutic aerosol and the target tissue
Summary
Peritoneal metastasis of gastrointestinal and gynecological origin are frequent with an estimated worldwide incidence of 1,000,000 new cases/year [1, 2]. Intraperitoneal chemotherapy has several pharmacological limitations, in particular poor tissue penetration and incomplete distribution of the drug within the peritoneal cavity [5]. Drugs administered into the peritoneal cavity are approved in the specific indications for intravenous delivery. These drugs have all been formulated for optimized intravenous delivery and are hydrophilic [6]. This is a strong limitation for application into a cavity limited by. Results: The enhanced IBUB (eIBUB) model allows measurements of tissue drug concentration, depth of tissue penetration and spatial distribution. The homogeneous morphology of the peritoneum enables standardized, Keywords: aerosol, alternative to animal models, cisplatin, doxorubicin, intraperitoneal chemotherapy, pressure, Pressurized Intraperitoneal Aerosol Chemotherapy (PIPAC)
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