Your search keyword '"Verena, Reupke"' showing total 10 results

1. Estimation of normal lung weight index in healthy female domestic pigs

Author

Antonio Fioccola, Rosmery Valentina Nicolardi, Tommaso Pozzi, Isabella Fratti, Federica Romitti, Francesca Collino, Verena Reupke, Gianluigi Li Bassi, Alessandro Protti, Alessandro Santini, Massimo Cressoni, Mattia Busana, Onnen Moerer, Luigi Camporota, and Luciano Gattinoni

Subjects

Medical emergencies. Critical care. Intensive care. First aid, RC86-88.9

Abstract

Abstract Introduction Lung weight is an important study endpoint to assess lung edema in porcine experiments on acute respiratory distress syndrome and ventilatory induced lung injury. Evidence on the relationship between lung–body weight relationship is lacking in the literature. The aim of this work is to provide a reference equation between normal lung and body weight in female domestic piglets. Materials and methods 177 healthy female domestic piglets from previous studies were included in the analysis. Lung weight was assessed either via a CT-scan before any experimental injury or with a scale after autopsy. The animals were randomly divided in a training (n = 141) and a validation population (n = 36). The relation between body weight and lung weight index (lung weight/body weight, g/kg) was described by an exponential function on the training population. The equation was tested on the validation population. A Bland–Altman analysis was performed to compare the lung weight index in the validation population and its theoretical value calculated with the reference equation. Results A good fit was found between the validation population and the exponential equation extracted from the training population (RMSE = 0.060). The equation to determine lung weight index from body weight was: $${\text{Lung}} {\text{Weight}} {\text{Index}} \left(\frac{{\text{g}}}{{\text{kg}}}\right)=26.26*{10}^{-0.011*{\text{Body}} {\text{Weight}} \left({\text{kg}}\right)}.$$ LungWeightIndex g kg = 26.26 ∗ 10 - 0.011 ∗ BodyWeight kg . At the Bland and Altman analyses, the mean bias between the real and the expected lung weight index was − 0.26 g/kg (95% CI − 0.96–0.43), upper LOA 3.80 g/kg [95% CI 2.59–5.01], lower LOA − 4.33 g/kg [95% CI = − 5.54–(− 3.12)]. Conclusions This exponential function might be a valuable tool to assess lung edema in experiments involving 16–50 kg female domestic piglets. The error that can be made due to the 95% confidence intervals of the formula is smaller than the one made considering the lung to body weight as a linear relationship.

Published

2024

2. Targeted endomyocardial biopsy guided by real-time cardiovascular magnetic resonance

Author

Christina Unterberg-Buchwald, Christian Oliver Ritter, Verena Reupke, Robin Niklas Wilke, Christine Stadelmann, Michael Steinmetz, Andreas Schuster, Gerd Hasenfuß, Joachim Lotz, and Martin Uecker

Subjects

Endomyocardial biopsy, CMR, Targeted biopsy, Real-time MRI, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

Abstract Background Endomyocardial biopsies (EMB) are an important diagnostic tool for myocarditis and other infiltrative cardiac diseases. Routinely, biopsies are obtained under fluoroscopic guidance with a substantial radiation burden. Despite procedural success, there is a large sampling error caused by missing the affected myocardium. Therefore, multiple (>6) biopsies are taken in the clinical setting. In cardiovascular magnetic resonance (CMR), late gadolinium enhancement (LGE) depicts areas of affected myocardium in myocarditis or in other infiltrative cardiomyopathies. Thus, targeted biopsy under real-time CMR image guidance might reduce the problem of sampling error. Methods Seven minipigs of the Goettingen strain underwent radiofrequency ablation in the left ventricle. At least two focal lesions were induced on the lateral wall in five and the apex in two animals. Each ablation lesion was created by two consecutive 30 sec ablations (max. 30 W, temperature 60–64 °C). Biopsies were taken immediately after lesion induction using a commercially available 7 F conventional bioptome under fluoroscopic guidance at the ablation site. Afterwards the animals underwent CMR and lesion visualization by LGE at 3T. The lesions were then targeted and biopsied under CMR-guidance using a MR-conditional bioptome guided by a steerable catheter. Interactive real-time (RT) visualization of the intervention on an in-room monitor was based on radial FLASH with nonlinear inverse reconstruction (NLINV) at a temporal resolution of 42 ms. All samples underwent a standard histological evaluation. Results Radiofrequency ablation was successful in all animals. Fluoroscopy-guided biopsies were performed with a success rate of 6/6 minipigs - resulting in a nonlethal pericardial effusion in one animal. Visualization of radiofrequency lesions by CMR was successful in 7/7 minipig, i.e. at least one lesion was clearly visible. Localization and tracking of the catheters and the bioptome using interactive control of the imaging plane was achieved in 6/6 MP; however in the animal with a large pericardial effusion after EMB under fluoroscopy no further EMB was attempted for safety reasons. Biopsies under interactive RT-CMR guidance were successfully performed in 5/6 animals, in one animal the bioptome reached the lesion, however the forceps did not cut out a sample. Specimens obtained under CMR guidance contained part of the lesion in 6/15 (40%) myocardial specimens and in 4/5 (80%) animals in which samples were achieved. Conventional biopsies revealed ablation lesions in 4/17 (23.5%) specimens in 3/6 minipigs (50%). Conclusion Focal lesions induced by radiofrequency ablation in a minipig model are a useful tool for CMR-guided biopsy studies. In contrast to fluoroscopy, CMR provides excellent visualization of lesions. Interactive real-time CMR allows excellent passive tracking of the instruments and EMB provides significantly superior sampling accuracy compared to fluoroscopy-guided biopsies. Nonetheless, further improvements of MR-compatible bioptomes and guiding catheters are essential before applying this method in a clinical setting.

Published

2017

3. CD8+-T Cells With Specificity for a Model Antigen in Cardiomyocytes Can Become Activated After Transverse Aortic Constriction but Do Not Accelerate Progression to Heart Failure

Author

Carina Gröschel, André Sasse, Sebastian Monecke, Charlotte Röhrborn, Leslie Elsner, Michael Didié, Verena Reupke, Gertrude Bunt, Andrew H. Lichtman, Karl Toischer, Wolfram-Hubertus Zimmermann, Gerd Hasenfuß, and Ralf Dressel

Subjects

autoimmunity, autoantigen, pressure overload, cytotoxic T cells, adoptive transfer, transgenic T cell receptor, Immunologic diseases. Allergy, RC581-607

Abstract

Heart failure due to pressure overload is frequently associated with inflammation. In addition to inflammatory responses of the innate immune system, autoimmune reactions of the adaptive immune system appear to be triggered in subgroups of patients with heart failure as demonstrated by the presence of autoantibodies against myocardial antigens. Moreover, T cell-deficient and T cell-depleted mice have been reported to be protected from heart failure induced by transverse aortic constriction (TAC) and we have shown recently that CD4+-helper T cells with specificity for an antigen in cardiomyocytes accelerate TAC-induced heart failure. In this study, we set out to investigate the potential contribution of CD8+-cytotoxic T cells with specificity to a model antigen (ovalbumin, OVA) in cardiomyocytes to pressure overload-induced heart failure. In 78% of cMy-mOVA mice with cardiomyocyte-specific OVA expression, a low-grade OVA-specific cellular cytotoxicity was detected after TAC. Adoptive transfer of OVA-specific CD8+-T cells from T cell receptor transgenic OT-I mice before TAC did not increase the risk of OVA-specific autoimmunity in cMy-mOVA mice. After TAC, again 78% of the mice displayed an OVA-specific cytotoxicity with on average only a three-fold higher killing of OVA-expressing target cells. More CD8+ cells were present after TAC in the myocardium of cMy-mOVA mice with OT-I T cells (on average 17.5/mm2) than in mice that did not receive OVA-specific CD8+-T cells (3.6/mm2). However, the extent of fibrosis was similar in both groups. Functionally, as determined by echocardiography, the adoptive transfer of OVA-specific CD8+-T cells did not significantly accelerate the progression from hypertrophy to heart failure in cMy-mOVA mice. These findings argue therefore against a major impact of cytotoxic T cells with specificity for autoantigens of cardiomyocytes in pressure overload-induced heart failure.

Published

2018

4. Does Iso-mechanical Power Lead to Iso-lung Damage?

Author

Michael Quintel, Luciano Gattinoni, O. Leopardi, Matteo Maria Macrì, Verena Reupke, David Jerome Aßmann, Peter Herrmann, Iacopo Pasticci, Mattia Busana, Günter Hahn, Francesco Vasques, Matteo Bonifazi, Federica Romitti, Lorenzo Giosa, Francesco Vassalli, Eleonora Duscio, John J. Marini, Onnen Moerer, and Hannah Grünhagen

Subjects

medicine.medical_specialty, Lung, Respiratory rate, business.industry, Hemodynamics, 030208 emergency & critical care medicine, Context (language use), respiratory system, Lung injury, respiratory tract diseases, 03 medical and health sciences, 0302 clinical medicine, Anesthesiology and Pain Medicine, Functional residual capacity, medicine.anatomical_structure, 030228 respiratory system, Internal medicine, Cardiology, Medicine, business, Tidal volume, Positive end-expiratory pressure

Abstract

BackgroundExcessive tidal volume, respiratory rate, and positive end-expiratory pressure (PEEP) are all potential causes of ventilator-induced lung injury, and all contribute to a single variable: the mechanical power. The authors aimed to determine whether high tidal volume or high respiratory rate or high PEEP at iso-mechanical power produce similar or different ventilator-induced lung injury.MethodsThree ventilatory strategies—high tidal volume (twice baseline functional residual capacity), high respiratory rate (40 bpm), and high PEEP (25 cm H2O)—were each applied at two levels of mechanical power (15 and 30 J/min) for 48 h in six groups of seven healthy female piglets (weight: 24.2 ± 2.0 kg, mean ± SD).ResultsAt iso-mechanical power, the high tidal volume groups immediately and sharply increased plateau, driving pressure, stress, and strain, which all further deteriorated with time. In high respiratory rate groups, they changed minimally at the beginning, but steadily increased during the 48 h. In contrast, after a sudden huge increase, they decreased with time in the high PEEP groups. End-experiment specific lung elastance was 6.5 ± 1.7 cm H2O in high tidal volume groups, 10.1 ± 3.9 cm H2O in high respiratory rate groups, and 4.5 ± 0.9 cm H2O in high PEEP groups. Functional residual capacity decreased and extravascular lung water increased similarly in these three categories. Lung weight, wet-to-dry ratio, and histologic scores were similar, regardless of ventilatory strategies and power levels. However, the alveolar edema score was higher in the low power groups. High PEEP had the greatest impact on hemodynamics, leading to increased need for fluids. Adverse events (early mortality and pneumothorax) also occurred more frequently in the high PEEP groups.ConclusionsDifferent ventilatory strategies, delivered at iso-power, led to similar anatomical lung injury. The different systemic consequences of high PEEP underline that ventilator-induced lung injury must be evaluated in the context of the whole body.Editor’s PerspectiveWhat We Already Know about This TopicWhat This Article Tells Us That Is New

Published

2020

5. Extracorporeal CO2 Removal

Author

Francesco Vasques, Francesca Collino, Michael Quintel, Luciano Gattinoni, Francesca Rapetti, Iacopo Pasticci, Tommaso Tonetti, Tim Behnemann, Francesco Cipulli, Onnen Moerer, Federica Romitti, Julia Niewenhuys, Eleonora Duscio, Francesco Vassalli, Verena Reupke, Duscio E., Cipulli F., Vasques F., Collino F., Rapetti F., Romitti F., Behnemann T., Niewenhuys J., Tonetti T., Pasticci I., Vassalli F., Reupke V., Moerer O., Quintel M., and Gattinoni L.

Subjects

Catheterization, Central Venous, minimally invasive extracorporeal life support, Swine, medicine.medical_treatment, 030204 cardiovascular system & hematology, Lung injury, Critical Care and Intensive Care Medicine, Extracorporeal, pCO2, Artificial lung, 03 medical and health sciences, 0302 clinical medicine, 030202 anesthesiology, medicine, Animals, carbon dioxide removal, Mechanical ventilation, Lung, business.industry, ventilator-induced lung injury, Blood flow, Carbon Dioxide, acute respiratory distress syndrome, extracorporeal membrane oxygenation, 3. Good health, extracorporeal carbon dioxide removal, Catheter, medicine.anatomical_structure, Anesthesia, Models, Animal, Respiratory Insufficiency, business, Ventilator Weaning

Abstract

Objectives Minimally invasive extracorporeal CO2 removal is an accepted supportive treatment in chronic obstructive pulmonary disease patients. Conversely, the potential of such technique in treating acute respiratory distress syndrome patients remains to be investigated. The aim of this study was: 1) to quantify membrane lung CO2 removal (VCO2ML) under different conditions and 2) to quantify the natural lung CO2 removal (VCO2NL) and to what extent mechanical ventilation can be reduced while maintaining total expired CO2 (VCO2tot = VCO2ML + VCO2NL) and arterial PCO2 constant. Design Experimental animal study. Setting Department of Experimental Animal Medicine, University of Gottingen, Germany. Subjects Eight healthy pigs (57.7 ± 5 kg). Interventions The animals were sedated, ventilated, and connected to the artificial lung system (surface 1.8 m, polymethylpentene membrane, filling volume 125 mL) through a 13F catheter. VCO2ML was measured under different combinations of inflow PCO2 (38.9 ± 3.3, 65 ± 5.7, and 89.9 ± 12.9 mm Hg), extracorporeal blood flow (100, 200, 300, and 400 mL/min), and gas flow (4, 6, and 12 L/min). At each setting, we measured VCO2ML, VCO2NL, lung mechanics, and blood gases. Measurements and main results VCO2ML increased linearly with extracorporeal blood flow and inflow PCO2 but was not affected by gas flow. The outflow PCO2 was similar regardless of inflow PCO2 and extracorporeal blood flow, suggesting that VCO2ML was maximally exploited in each experimental condition. Mechanical ventilation could be reduced by up to 80-90% while maintaining a constant PaCO2. Conclusions Minimally invasive extracorporeal CO2 removal removes a relevant amount of CO2 thus allowing mechanical ventilation to be significantly reduced depending on extracorporeal blood flow and inflow PCO2. Extracorporeal CO2 removal may provide the physiologic prerequisites for controlling ventilator-induced lung injury.

Published

2019

6. Does Iso-mechanical Power Lead to Iso-lung Damage?: An Experimental Study in a Porcine Model

Author

Francesco, Vassalli, Iacopo, Pasticci, Federica, Romitti, Eleonora, Duscio, David Jerome, Aßmann, Hannah, Grünhagen, Francesco, Vasques, Matteo, Bonifazi, Mattia, Busana, Matteo Maria, Macrì, Lorenzo, Giosa, Verena, Reupke, Peter, Herrmann, Günter, Hahn, Orazio, Leopardi, Onnen, Moerer, Michael, Quintel, John J, Marini, and Luciano, Gattinoni

Subjects

Positive-Pressure Respiration, Animals, Newborn, Swine, Ventilator-Induced Lung Injury, Models, Animal, Respiratory Mechanics, Tidal Volume, Animals, Female

Abstract

Excessive tidal volume, respiratory rate, and positive end-expiratory pressure (PEEP) are all potential causes of ventilator-induced lung injury, and all contribute to a single variable: the mechanical power. The authors aimed to determine whether high tidal volume or high respiratory rate or high PEEP at iso-mechanical power produce similar or different ventilator-induced lung injury.Three ventilatory strategies-high tidal volume (twice baseline functional residual capacity), high respiratory rate (40 bpm), and high PEEP (25 cm H2O)-were each applied at two levels of mechanical power (15 and 30 J/min) for 48 h in six groups of seven healthy female piglets (weight: 24.2 ± 2.0 kg, mean ± SD).At iso-mechanical power, the high tidal volume groups immediately and sharply increased plateau, driving pressure, stress, and strain, which all further deteriorated with time. In high respiratory rate groups, they changed minimally at the beginning, but steadily increased during the 48 h. In contrast, after a sudden huge increase, they decreased with time in the high PEEP groups. End-experiment specific lung elastance was 6.5 ± 1.7 cm H2O in high tidal volume groups, 10.1 ± 3.9 cm H2O in high respiratory rate groups, and 4.5 ± 0.9 cm H2O in high PEEP groups. Functional residual capacity decreased and extravascular lung water increased similarly in these three categories. Lung weight, wet-to-dry ratio, and histologic scores were similar, regardless of ventilatory strategies and power levels. However, the alveolar edema score was higher in the low power groups. High PEEP had the greatest impact on hemodynamics, leading to increased need for fluids. Adverse events (early mortality and pneumothorax) also occurred more frequently in the high PEEP groups.Different ventilatory strategies, delivered at iso-power, led to similar anatomical lung injury. The different systemic consequences of high PEEP underline that ventilator-induced lung injury must be evaluated in the context of the whole body.

Published

2020

7. Positive End-expiratory Pressure and Mechanical Power

Author

Peter Herrmann, Karin Holke, Verena Reupke, Giorgia Maiolo, Francesco Cipulli, Günter Hahn, Tommaso Tonetti, Luigi Camporota, John J. Marini, Julia Niewenhuys, Francesca Collino, Francesca Rapetti, Francesco Vasques, Tim Behnemann, Michael Quintel, Onnen Moerer, Luciano Gattinoni, Eleonora Duscio, Federica Romitti, Collino F., Rapetti F., Vasques F., Maiolo G., Tonetti T., Romitti F., Niewenhuys J., Behnemann T., Camporota L., Hahn G., Reupke V., Holke K., Herrmann P., Duscio E., Cipulli F., Moerer O., Marini J.J., Quintel M., and Gattinoni L.

Subjects

medicine.medical_specialty, Lung, VILI, Swine, business.industry, Ventilator-Induced Lung Injury, Lung injury, respiratory system, Positive-Pressure Respiration, Disease Models, Animal, 03 medical and health sciences, 0302 clinical medicine, Anesthesiology and Pain Medicine, medicine.anatomical_structure, 030202 anesthesiology, Internal medicine, medicine, Cardiology, Animals, business, 030217 neurology & neurosurgery, Positive end-expiratory pressure, Mechanical energy

Abstract

EDITOR’S PERSPECTIVEWhat We Already Know about This TopicPositive end-expiratory pressure protects against ventilation-induced lung injury by improving homogeneity of ventilation, but positive end-expiratory pressure contributes to the mechanical power required to ventilate the lungWhat This Article Tells Us That Is NewThis in vivo study (36 pigs mechanically ventilated in the prone position) suggests that low levels of positive end-expiratory pressure reduce injury associated with atelectasis, and above a threshold level of power, positive end-expiratory pressure causes lung injury and adverse hemodynamicsBackgroundPositive end-expiratory pressure is usually considered protective against ventilation-induced lung injury by reducing atelectrauma and improving lung homogeneity. However, positive end-expiratory pressure, together with tidal volume, gas flow, and respiratory rate, contributes to the mechanical power required to ventilate the lung. This study aimed at investigating the effects of increasing mechanical power by selectively modifying its positive end-expiratory pressure component.MethodsThirty-six healthy piglets (23.3 ± 2.3 kg) were ventilated prone for 50 h at 30 breaths/min and with a tidal volume equal to functional residual capacity. Positive end-expiratory pressure levels (0, 4, 7, 11, 14, and 18 cm H2O) were applied to six groups of six animals. Respiratory, gas exchange, and hemodynamic variables were recorded every 6 h. Lung weight and wet-to-dry ratio were measured, and histologic samples were collected.ResultsLung mechanical power was similar at 0 (8.8 ± 3.8 J/min), 4 (8.9 ± 4.4 J/min), and 7 (9.6 ± 4.3 J/min) cm H2O positive end-expiratory pressure, and it linearly increased thereafter from 15.5 ± 3.6 J/min (positive end-expiratory pressure, 11 cm H2O) to 18.7 ± 6 J/min (positive end-expiratory pressure, 14 cm H2O) and 22 ± 6.1 J/min (positive end-expiratory pressure, 18 cm H2O). Lung elastances, vascular congestion, atelectasis, inflammation, and septal rupture decreased from zero end-expiratory pressure to 4 to 7 cm H2O (P < 0.0001) and increased progressively at higher positive end-expiratory pressure. At these higher positive end-expiratory pressure levels, striking hemodynamic impairment and death manifested (mortality 0% at positive end-expiratory pressure 0 to 11 cm H2O, 33% at 14 cm H2O, and 50% at 18 cm H2O positive end-expiratory pressure). From zero end-expiratory pressure to 18 cm H2O, mean pulmonary arterial pressure (from 19.7 ± 5.3 to 32.2 ± 9.2 mmHg), fluid administration (from 537 ± 403 to 2043 ± 930 ml), and noradrenaline infusion (0.04 ± 0.09 to 0.34 ± 0.31 μg · kg−1 · min−1) progressively increased (P < 0.0001). Lung weight and lung wet-to-dry ratios were not significantly different across the groups. The lung mechanical power level that best discriminated between more versus less severe damage was 13 ± 1 J/min.ConclusionsLess than 7 cm H2O positive end-expiratory pressure reduced atelectrauma encountered at zero end-expiratory pressure. Above a defined power threshold, sustained positive end-expiratory pressure contributed to potentially lethal lung damage and hemodynamic impairment.

Published

2019

8. Detecting Early Markers of Ventilator-Associated Pneumonia by Analysis of Exhaled Gas

Author

Thorsten Perl, Ursula Telgheder, Wolfgang Vautz, Michael Quintel, Jakob Luther, Christian Dullin, Barbara Cambiaghi, Verena Reupke, Nils Kunze-Szikszay, Karoline Walliser, Cornelia Zscheppank, and Felix Bremmer

Subjects

Host response, Sensitive analysis, Chemie, Critical Care and Intensive Care Medicine, Severity of Illness Index, Gas Chromatography-Mass Spectrometry, 03 medical and health sciences, 0302 clinical medicine, Ion Mobility Spectrometry, medicine, Animals, Lung, Volatile Organic Compounds, business.industry, Ventilator-associated pneumonia, Pneumonia, Ventilator-Associated, 030208 emergency & critical care medicine, medicine.disease, 3. Good health, Pneumonia, 030228 respiratory system, Exhalation, Immunology, Female, Rabbits, business, Biomarkers

Abstract

The detection of microbial volatile organic compounds or host response markers in the exhaled gas could give an earlier diagnosis of ventilator-associated pneumonia. Gas chromatography-ion mobility spectrometry enables noninvasive, rapid, and sensitive analysis of exhaled gas. Using a rabbit model of ventilator-associated pneumonia we determined if gas chromatography-ion mobility spectrometry is able to detect 1) ventilator-associated pneumonia specific changes and 2) bacterial species-specific changes in the exhaled gas.Experimental in vivo study.University research laboratory.Female New Zealand White rabbits.Animals were anesthetized and mechanically ventilated. To induce changes in the composition of exhaled gas we induced ventilator-associated pneumonia via endobronchial instillation of either Escherichia coli group (n = 11) or Pseudomonas aeruginosa group (n = 11) after 2 hours of mechanical ventilation. In a control group (n = 11) we instilled sterile lysogeny broth endobronchially.Gas chromatography-ion mobility spectrometry gas analysis, CT scans of the lungs, and blood samples were obtained at four measurement points during the 10 hours of mechanical ventilation. The volatile organic compound patterns in the exhaled gas were compared and correlated with ventilator-associated pneumonia severity. Sixty-seven peak areas showed changes in signal intensity in the serial gas analyses. The signal intensity changes in 10 peak regions differed between the groups. Five peak areas (P_648_36, indole, P_714_278, P_700_549, and P_727_557) showed statistically significant changes of signal intensity.This is the first in vivo study that shows the potential of gas chromatography-ion mobility spectrometry for early detection of ventilator-associated pneumonia specific volatile organic compounds and species differentiation by noninvasive analyses of exhaled gas.

Published

2019

9. Total intravenous anaesthesia using propofol and sufentanil allows controlled long-term ventilation in rabbits without neuromuscular blocking agents

Author

Karoline Walliser, Sarah Kimmina, Nils Kunze-Szikszay, Anke Schraepler, Verena Reupke, Michael Quintel, and Thorsten Perl

Subjects

040301 veterinary sciences, Sufentanil, medicine.medical_treatment, 0403 veterinary science, 03 medical and health sciences, 0302 clinical medicine, medicine, Animals, Propofol, Mechanical ventilation, Neuromuscular Blockade, General Veterinary, business.industry, 030208 emergency & critical care medicine, 04 agricultural and veterinary sciences, Neuromuscular Blocking Agents, Respiration, Artificial, Blood pressure, Anesthesia, Reflex, Breathing, Anesthesia, Intravenous, Animal Science and Zoology, Rabbits, business, Anesthetics, Intravenous, medicine.drug

Abstract

The aim of this study was to evaluate a total intravenous anaesthesia (TIVA) protocol using propofol and sufentanil without neuromuscular blocking agents (NBAs) for a non-recovery lung pathology study in rabbits including 10 h of pressure-controlled ventilation. TIVA was started with 20 mg/kg/h propofol and 0.5 µg/kg/h sufentanil. The depth of anaesthesia was assessed by reflex testing and monitoring of spontaneous movements or respiratory efforts. Vital parameters were monitored to assess the effects of the TIVA protocol. The infusion rates were increased whenever reflex testing indicated inadequate depth of anaesthesia, and were reduced when vital parameters indicated unnecessarily deep levels. Median infusion rates of 35 mg/kg/h propofol and 2.0 µg/kg/h sufentanil were needed to ensure an adequate depth of anaesthesia. This protocol suppressed spontaneous movements, breathing and palpebral reflexes, but was unable to suppress corneal and pedal withdrawal reflexes. Since significant drops in arterial blood pressure (ABP) were observed and the animals were not exposed to painful procedures, positive corneal and pedal withdrawal reflexes were tolerated. In conclusion, propofol and sufentanil is a suitable combination for long-term anaesthesia in non-recovery lung pathology models in rabbits without painful procedures. ABP must be monitored carefully because of the circulatory side-effects, but it is an inappropriate surrogate marker for depth of anaesthesia. Due to the lack of neuromuscular blockade this TIVA protocol allows the adjustment of infusion rates based on reflex testing. The resulting decreased risk of unnoticed awareness is a decisive refinement in anaesthesia for similar studies including long-term mechanical ventilation in rabbits.

Published

2016

10. Early abiraterone treatment after surgical castration in in vivo castration resistant prostate cancer (CRPC) tumors in nude mice

Author

Paul Thelen, Felix Bremmer, Verena Reupke, and Hubertus Jarry

Subjects

Cancer Research, Matrigel, medicine.medical_specialty, business.industry, Castration resistant, medicine.disease, Androgen receptor, chemistry.chemical_compound, Prostate cancer, Castration, Endocrinology, Oncology, chemistry, In vivo, Internal medicine, Surgical castration, medicine, business, Antagonism

Abstract

263 Background: ADT is the initial therapy for advanced prostate cancer, and androgen biosynthesis inhibitors (abiraterone-acetate, AA) reveal clinical survival benefit for CRPC. On CRPC progression, therapy sequencing towards androgen receptor (AR) antagonism is applied and AA withdrawal / re-challenge strategies (+AA-AA+AA) succeeded in several case reports. Here we established a VCaP-tumor mouse model for a +AA-AA+AA-sequence and external testosterone-boosts (+AA[-AA+T]+AA). Methods: 20 tumor bearing mice (from 106 VCaP in Matrigel) received surgical ADT and then +AA-AA+AA, (AA intraperitoneal 70mg/kg, daily [Janssen-Cilag]), or +AA[-AA+T]+AA (+0.6 µl/kg Nebido [250mg testosterone-undecaonate/ml, Jenapharm]). Tumor growth was monitored with calipers. When tumors grew > 200 mm3, animals were castrated and treatment-sequences began when CRPC growth became evident (n = 15) or early one week after castration (n = 5). Expression analyses were performed with Experion, CSX-96 and ChemiDoc, chemicals, software (BioRad). Steroids were quantified by Dept. Clin. Chemistry. Results: 20 tumor-bearing mice received ADT. To interfere with ADT failure for 15 mice +AA-AA+AA (n = 7) or +AA[-AA+T]+AA (n = 8) commenced when tumors doubled within two weeks. Animals benefited a reduction of up to 210 mm3 receiving +AA-AA+AA, whereas a T-Boost in +AA[-AA+T]+AA revealed a loss of solid tumor mass as mean 42% (+/-21%) liquid effusion. No complete remission was observed, tumors > 1 cm3 were considered dead-of-disease (DOD). Another group (n = 5) was AA-treated one week after castration. There +AA-AA+AA and +AA[-AA+T]+AA resulted for one animal in DOD, however tumors of up to 990 mm3 underwent complete remissions (n = 4) and tumor-free untreated survival. AA-withdrawal is associated with progesterone decrease and DHEA increase. AR (+ AR-Vs) decreases to 95% expression immediately after -AA and to 39% (no AR-Vs) upon +T. Conclusions: Therapy sequences with AA-withdrawal/rechallenge may lead to tumor regression and complete tumor-free survival. Concomitant with tumor regression upon AA-withdrawal, AR overexpression is reduced, which may be boosted with testosterone supplementation.

Published

2016