Mapping regional strain in anesthetised healthy subjects during spontaneous ventilation

Cruces, Pablo; Erranz, Benjamín; Lillo, Felipe; Sarabia‐Vallejos, Mauricio A.; Iturrieta, Pablo; Morales, Felipe; Blaha, Katherine; Medina, Tania; Rubio, Franco Díaz; Hurtado, Daniel E.

doi:10.1136/bmjresp-2019-000423

Cited by 8 publications

(11 citation statements)

References 29 publications

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“…The scanner includes a physiological monitoring system to track the breathing of the subject in order to deliver time-resolved four-dimensional (4D) image sequences. In the SB-group, respiratory gating based on the thorax movement was employed to reduce the effect of motion artifacts [ 10 ], while in the MV-group, the acquisition was controlled by the mechanical ventilator cycles. Scans were performed using a source voltage of 70 kV and a source current of 140 μA.…”

Section: Methodsmentioning

confidence: 99%

Progression of regional lung strain and heterogeneity in lung injury: assessing the evolution under spontaneous breathing and mechanical ventilation

Hurtado

Erranz

Lillo

et al. 2020

Ann. Intensive Care

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Background Protective mechanical ventilation (MV) aims at limiting global lung deformation and has been associated with better clinical outcomes in acute respiratory distress syndrome (ARDS) patients. In ARDS lungs without MV support, the mechanisms and evolution of lung tissue deformation remain understudied. In this work, we quantify the progression and heterogeneity of regional strain in injured lungs under spontaneous breathing and under MV. Methods Lung injury was induced by lung lavage in murine subjects, followed by 3 h of spontaneous breathing (SB-group) or 3 h of low V t mechanical ventilation (MV-group). Micro-CT images were acquired in all subjects at the beginning and at the end of the ventilation stage following induction of lung injury. Regional strain, strain progression and strain heterogeneity were computed from image-based biomechanical analysis. Three-dimensional regional strain maps were constructed, from which a region-of-interest (ROI) analysis was performed for the regional strain, the strain progression, and the strain heterogeneity. Results After 3 h of ventilation, regional strain levels were significantly higher in 43.7% of the ROIs in the SB-group. Significant increase in regional strain was found in 1.2% of the ROIs in the MV-group. Progression of regional strain was found in 100% of the ROIs in the SB-group, whereas the MV-group displayed strain progression in 1.2% of the ROIs. Progression in regional strain heterogeneity was found in 23.4% of the ROIs in the SB-group, while the MV-group resulted in 4.7% of the ROIs showing significant changes. Deformation progression is concurrent with an increase of non-aerated compartment in SB-group (from 13.3% ± 1.6% to 37.5% ± 3.1%), being higher in ventral regions of the lung. Conclusions Spontaneous breathing in lung injury promotes regional strain and strain heterogeneity progression. In contrast, low V t MV prevents regional strain and heterogeneity progression in injured lungs.

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Section: Methodsmentioning

confidence: 99%

Progression of regional lung strain and heterogeneity in lung injury: assessing the evolution under spontaneous breathing and mechanical ventilation

Hurtado

Erranz

Lillo

et al. 2020

Ann. Intensive Care

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“…For example, during normal tidal breathing, the lungs inflate and deflate with a volumetric strain of 20−50% and a frequency of 12−20 breaths per minutes. 232 Therefore, an adhesive applied to the lungs will experience distension and contraction more than ten thousand times a day. The resulting mechanical stresses exerted on the adhesive matrix may not cause adhesive failure over a few cycles, but may after multiple cycles due to the fatigue of the matrix.…”

Section: Solution Additionmentioning

confidence: 99%

Polymeric Tissue Adhesives

2021

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Polymeric tissue adhesives provide versatile materials for wound management and are widely used in a variety of medical settings ranging from minor to life-threatening tissue injuries. Compared to the traditional methods of wound closure (i.e., suturing and stapling), they are relatively easy to use, enable rapid application, and introduce minimal tissue damage. Furthermore, they can act as hemostats to control bleeding and provide a tissue-healing environment at the wound site. Despite their numerous current applications, tissue adhesives still face several limitations and unresolved challenges (e.g., weak adhesion strength and poor mechanical properties) that limit their use, leaving ample room for future improvements. Successful development of next-generation adhesives will likely require a holistic understanding of the chemical and physical properties of the tissue-adhesive interface, fundamental mechanisms of tissue adhesion, and requirements for specific clinical applications. In this review, we discuss a set of rational guidelines for design of adhesives, recent progress in the field along with examples of commercially available adhesives and those under development, tissue-specific considerations, and finally potential functions for future adhesives. Advances in tissue adhesives will open new avenues for wound care and potentially provide potent therapeutics for various medical applications.

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“…Recently, we developed a 4D tomographic study that employs image-based biomechanical analysis [49] to unveil the volumetric distribution of regional deformation of the whole lung in subjects without MV. In healthy sedated rats under (unassisted) spontaneously breathing, we observed volumetric regional strain and strain heterogeneity, quantifying the magnitude of these deformation indices and its progression in time [50]. Given the fact that regional strain and heterogeneity are present during a normal respiratory cycle without harming the lung leads to the question: why P-SILI does not develop in normal lungs deformed by physiologic Vt?…”

Section: P-sili Without Positive Pressure Ventilationmentioning

confidence: 99%

A physiological approach to understand the role of respiratory effort in the progression of lung injury in SARS-CoV-2 infection

et al. 2020

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Deterioration of lung function during the first week of COVID-19 has been observed when patients remain with insufficient respiratory support. Patient self-inflicted lung injury (P-SILI) is theorized as the responsible, but there is not robust experimental and clinical data to support it. Given the limited understanding of P-SILI, we describe the physiological basis of P-SILI and we show experimental data to comprehend the role of regional strain and heterogeneity in lung injury due to increased work of breathing. In addition, we discuss the current approach to respiratory support for COVID-19 under this point of view.

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Mapping regional strain in anesthetised healthy subjects during spontaneous ventilation

Cited by 8 publications

References 29 publications

Progression of regional lung strain and heterogeneity in lung injury: assessing the evolution under spontaneous breathing and mechanical ventilation

Progression of regional lung strain and heterogeneity in lung injury: assessing the evolution under spontaneous breathing and mechanical ventilation

Polymeric Tissue Adhesives

A physiological approach to understand the role of respiratory effort in the progression of lung injury in SARS-CoV-2 infection

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