Your search keyword '"Carmen Ainola"' showing total 5 results

1. Comparative analysis of novel esophageal pressure monitoring catheters versus commercially available alternatives in a biomechanical model of the thoracic cavity

Author

Gabriella Abbate, Sebastiano Maria Colombo, Clayton Semenzin, Noriko Sato, Keibun Liu, Carmen Ainola, Angelo Milani, Gabriele Fior, Nchafatso Obonyo, Nicole White, Davide Chiumello, Jo Pauls, Jacky Y. Suen, John F. Fraser, and Gianluigi Li Bassi

Subjects

Esophageal pressure, Nasogastric catheter, Trans-esophageal pressure, Mechanical ventilation, Intensive care unit, Medicine, Science

Abstract

Abstract Transpulmonary pressure can be estimated using esophageal balloon (EB) catheters, which come in a variety of manufacturing configurations. We assessed the performance of novel polyurethane EB designs, Aspisafe NG and NG+, against existing alternatives. We created a biomechanical model of the chest cavity using a plastic chamber and an ex-vivo porcine esophagus. The chamber was pressurized (− 20 and + 20 cmH2O) to simulate pleural pressures. We conducted tests with various EB inflation volumes and measured transesophageal pressure (TEP). TEP measurement was defined as accurate when the difference between pressure within the EB and chamber was 0 ± 1 cmH2O. We computed the minimal (Vaccuracy-min) and maximal (Vaccuracy-max) EB inflation volumes of accuracy. Inflation volumes were further validated using a surrogate method derived by the clinically validated positive pressure occlusion test (PPOT). When the esophageal balloons were filled with inflation volumes within the range provided by the manufacturers, the accuracy of TEP measurements was marginal. Our tests found median Vaccuracy-min across EB of 0.00–0.50 mL (p = 0.130), whereas Vaccuracy-max ranged 0.50–2.25 mL (p = 0.002). Post PPOT validation, median TEP was − 0.4 cmH2O (− 1.5 to 0.3) (p

Published

2024

2. An appraisal of lung computer tomography in very early anti-inflammatory treatment of two different ovine ARDS phenotypes

Author

Karin Wildi, Sebastiano Maria Colombo, Daniel McGuire, Carmen Ainola, Silver Heinsar, Noriko Sato, Kei Sato, Keibun Liu, Mahé Bouquet, Emily Wilson, Margaret Passmore, Kieran Hyslop, Samantha Livingstone, Marianna Di Feliciantonio, Wendy Strugnell, Chiara Palmieri, Jacky Suen, Gianluigi Li Bassi, and John Fraser

Subjects

Medicine, Science

Abstract

Abstract Mortality and morbidity of Acute Respiratory Distress Syndrome (ARDS) are largely unaltered. A possible new approach to treatment of ARDS is offered by the discovery of inflammatory subphenotypes. In an ovine model of ARDS phenotypes, matching key features of the human subphenotypes, we provide an imaging characterization using computer tomography (CT). Nine animals were randomized into (a) OA (oleic acid, hypoinflammatory; n = 5) and (b) OA-LPS (oleic acid and lipopolysaccharides, hyperinflammatory; n = 4). 48 h after ARDS induction and anti-inflammatory treatment, CT scans were performed at high (H) and then low (L) airway pressure. After CT, the animals were euthanized and lung tissue was collected. OA-LPS showed a higher air fraction and OA a higher tissue fraction, resulting in more normally aerated lungs in OA-LPS in contrast to more non-aerated lung in OA. The change in lung and air volume between H and L was more accentuated in OA-LPS, indicating a higher recruitment potential. Strain was higher in OA, indicating a higher level of lung damage, while the amount of lung edema and histological lung injury were largely comparable. Anti-inflammatory treatment might be beneficial in terms of overall ventilated lung portion and recruitment potential, especially in the OA-LPS group.

Published

2024

3. Application of anti-inflammatory treatment in two different ovine Acute Respiratory Distress Syndrome injury models: a preclinical randomized intervention study

Author

Karin Wildi, Samantha Livingstone, Carmen Ainola, Sebastiano Maria Colombo, Silver Heinsar, Noriko Sato, Kei Sato, Mahé Bouquet, Emily Wilson, Gabriella Abbate, Margaret Passmore, Kieran Hyslop, Keibun Liu, Xiaomeng Wang, Chiara Palmieri, Louise E. See Hoe, Jae-Seung Jung, Katrina Ki, Christian Mueller, John Laffey, Paolo Pelosi, Gianluigi Li Bassi, Jacky Suen, and John Fraser

Subjects

Medicine, Science

Abstract

Abstract Whilst the presence of 2 subphenotypes among the heterogenous Acute Respiratory Distress Syndrome (ARDS) population is becoming clinically accepted, subphenotype-specific treatment efficacy has yet to be prospectively tested. We investigated anti-inflammatory treatment in different ARDS models in sheep, previously shown similarities to human ARDS subphenotypes, in a preclinical, randomized, blinded study. Thirty anesthetized sheep were studied up to 48 h and randomized into: (a) OA: oleic acid (n = 15) and (b) OA-LPS: oleic acid and subsequent lipopolysaccharide (n = 15) to achieve a PaO2/FiO2 ratio of

Published

2023

4. Effect of flow change on brain injury during an experimental model of differential hypoxaemia in cardiogenic shock supported by extracorporeal membrane oxygenation

Author

Sacha Rozencwajg, Silver Heinsar, Karin Wildi, Jae‐Seung Jung, Sebastiano Maria Colombo, Chiara Palmieri, Kei Sato, Carmen Ainola, Xiaomeng Wang, Gabriella Abbate, Noriko Sato, Wayne B. Dyer, Samantha Livingstone, Leticia Helms, Nicole Bartnikowski, Mahe Bouquet, Margaret R. Passmore, Kieran Hyslop, Bruno Vidal, Janice D. Reid, Daniel McGuire, Emily S. Wilson, Indrek Rätsep, Roberto Lorusso, Matthieu Schmidt, Jacky Y. Suen, Gianluigi Li Bassi, and John F. Fraser

Subjects

Medicine, Science

Abstract

Abstract Differential hypoxaemia (DH) is common in patients supported by femoral veno-arterial extracorporeal membrane oxygenation (V-A ECMO) and can cause cerebral hypoxaemia. To date, no models have studied the direct impact of flow on cerebral damage. We investigated the impact of V-A ECMO flow on brain injury in an ovine model of DH. After inducing severe cardiorespiratory failure and providing ECMO support, we randomised six sheep into two groups: low flow (LF) in which ECMO was set at 2.5 L min−1 ensuring that the brain was entirely perfused by the native heart and lungs, and high flow (HF) in which ECMO was set at 4.5 L min−1 ensuring that the brain was at least partially perfused by ECMO. We used invasive (oxygenation tension—PbTO2, and cerebral microdialysis) and non-invasive (near infrared spectroscopy—NIRS) neuromonitoring, and euthanised animals after five hours for histological analysis. Cerebral oxygenation was significantly improved in the HF group as shown by higher PbTO2 levels (+ 215% vs − 58%, p = 0.043) and NIRS (67 ± 5% vs 49 ± 4%, p = 0.003). The HF group showed significantly less severe brain injury than the LF group in terms of neuronal shrinkage, congestion and perivascular oedema (p

Published

2023

5. An innovative ovine model of severe cardiopulmonary failure supported by veno-arterial extracorporeal membrane oxygenation

Author

Silver Heinsar, Jae-Seung Jung, Sebastiano Maria Colombo, Sacha Rozencwajg, Karin Wildi, Kei Sato, Carmen Ainola, Xiaomeng Wang, Gabriella Abbate, Noriko Sato, Wayne Bruce Dyer, Samantha Annie Livingstone, Leticia Pretti Pimenta, Nicole Bartnikowski, Mahe Jeannine Patricia Bouquet, Margaret Passmore, Bruno Vidal, Chiara Palmieri, Janice D. Reid, Haris M. Haqqani, Daniel McGuire, Emily Susan Wilson, Indrek Rätsep, Roberto Lorusso, Jacky Y. Suen, Gianluigi Li Bassi, and John F. Fraser

Subjects

Medicine, Science

Abstract

Abstract Refractory cardiogenic shock (CS) often requires veno-arterial extracorporeal membrane oxygenation (VA-ECMO) to sustain end-organ perfusion. Current animal models result in heterogenous cardiac injury and frequent episodes of refractory ventricular fibrillation. Thus, we aimed to develop an innovative, clinically relevant, and titratable model of severe cardiopulmonary failure. Six sheep (60 ± 6 kg) were anaesthetized and mechanically ventilated. VA-ECMO was commenced and CS was induced through intramyocardial injections of ethanol. Then, hypoxemic/hypercapnic pulmonary failure was achieved, through substantial decrease in ventilatory support. Echocardiography was used to compute left ventricular fractional area change (LVFAC) and cardiac Troponin I (cTnI) was quantified. After 5 h, the animals were euthanised and the heart was retrieved for histological evaluations. Ethanol (58 ± 23 mL) successfully induced CS in all animals. cTnI levels increased near 5000-fold. CS was confirmed by a drop in systolic blood pressure to 67 ± 14 mmHg, while lactate increased to 4.7 ± 0.9 mmol/L and LVFAC decreased to 16 ± 7%. Myocardial samples corroborated extensive cellular necrosis and inflammatory infiltrates. In conclusion, we present an innovative ovine model of severe cardiopulmonary failure in animals on VA-ECMO. This model could be essential to further characterize CS and develop future treatments.

Published

2021