Bronchoscopic lung volume reduction in emphysema: a review.

PURPOSE OF REVIEW: Chronic obstructive pulmonary disease (COPD) poses a substantial burden on the healthcare system and is currently considered the sixth leading cause of death in the United States. Emphysema, as evidenced by severe air-trapping in patients with COPD, leads to significant dyspnea and morbidity. Lung volume reduction via surgery or minimally invasive endobronchial interventions are currently available, which improve lung function and quality of life. RECENT FINDINGS: Newer studies have noted a survival benefit in patients post bronchoscopic lung volume reduction vs. those subjected to standard of care. The presence of collateral ventilation is one of the most common impeding factors to placing endobronchial valves, and if placed, these patients might not achieve lobar atelectasis; however, there are newer modalities that are now available for patients with collateral ventilation which we have described. SUMMARY: Combining standard of care treatment that includes smoking cessation, bronchodilators, preventive care including vaccinations, pulmonary rehabilitation, and endobronchial treatment using various interventions in decreasing hyperinflation improves quality of life and may improve survival and hence significantly reduce the burden of COPD on healthcare.

The role of bronchoscopy in the multidisciplinary approach to benign tracheal stenosis.

Benign tracheal stenosis can cause dyspnea, wheezing, and cough mimicking other obstructive lung diseases which often leads to a delay in the diagnosis. Risk factors and etiologies for tracheal strictures include autoimmune diseases, infection, gastro-esophageal reflux disease (GERD), radiation injury and iatrogenic factors such as post-intubation and post-tracheostomy. Once suspected, tracheal strictures are diagnosed by performing a thorough evaluation involving clinical exam, laboratory workup, pulmonary function test, chest imaging and bronchoscopy. Bronchoscopy plays a pivotal role in the diagnosis of stenosis and along with the imaging and physiologic assessments leads to a proper description of the stenosis based on all parameters that matters for management. Surgical resection provides a definitive management in most patients with idiopathic or post intubation/tracheostomy stenosis, however, factors such as severe co-morbidities, length and location of the stricture can preclude patients from undergoing curative surgery. Several bronchoscopic interventions including mechanical or laser assisted dilation, electrosurgery (ES), airway stenting and pharmacological treatment with mitomycin C (MMC) and intralesional steroid have been reported in the literature for management of patients who are not surgical candidates. Herein, we review the role of bronchoscopy and illustrate the importance of a multi-disciplinary team (MDT) approach comprising of interventional pulmonologists, thoracic surgeons and otorhinolaryngologists in the diagnosis and management of patients with benign tracheal stenosis.

Advanced Imaging for Robotic Bronchoscopy: A Review.

Recent advances in navigational platforms have led bronchoscopists to make major strides in diagnostic interventions for pulmonary parenchymal lesions. Over the last decade, multiple platforms including electromagnetic navigation and robotic bronchoscopy have allowed bronchoscopists to safely navigate farther into the lung parenchyma with increased stability and accuracy. Limitations persist, even with these newer technologies, in achieving a similar or higher diagnostic yield when compared to the transthoracic computed tomography (CT) guided needle approach. One of the major limitations to this effect is due to CT-to-body divergence. Real-time feedback that better defines the tool-lesion relationship is vital and can be obtained with additional imaging using radial endobronchial ultrasound, C-arm based tomosynthesis, cone-beam CT (fixed or mobile), and O-arm CT. Herein, we describe the role of this adjunct imaging with robotic bronchoscopy for diagnostic purposes, describe potential strategies to counteract the CT-to-body divergence phenomenon, and address the potential role of advanced imaging for lung tumor ablation.

Post hypoxic myoclonus: A tale of two minds.

Post hypoxic myoclonus (PHM) is considered a poor prognostic sign and may influence decisions regarding withdrawal of treatment. PHM is generally categorized in literature as either acute or chronic (also commonly referred to as Lance-Adams Syndrome) based on the onset of myoclonus. However, it may be more accurate to differentiate between the various presentations of PHM based on the clinical characteristics and electroencephalogram (EEG) findings for prognostication. Here, we describe a case of a 33-year-old female who presented after a cardiopulmonary arrest. MRI of the brain and cervical spine on admission were unremarkable. Twelve hours later, she developed generalized, stimulus-sensitive myoclonus suggestive of acute PHM. Various medications were trialed, and her symptoms eventually improved on clonazepam. On day 14, she started having resting and intention myoclonus, and dysarthria, consistent with LAS. Several adjustments were again made to her regimen, and she was eventually switched from clonazepam to baclofen which improved her resting myoclonus. This case highlights that PHM can present differently and have a markedly different outcome. It is important to develop a better understanding of the various types of PHM so as to avoid premature withdrawal of care.

Rapid Intensive Care Unit Onboarding in Response to a Pandemic.

BACKGROUND: In the wake of the coronavirus disease 2019 (COVID-19) pandemic, hospital resources have been stretched to their limits. We introduced an innovative course to rapidly on-board a group of non-intensive care unit (ICU) nurse practitioners as they begin to practice working in a critical care setting. OBJECTIVE: To assess whether a brief educational course could improve non-ICU practitioners' knowledge and comfort in practicing in an intensive care setting. METHODS: We implemented a multi-strategy blended 12-week curriculum composed of bedside teaching, asynchronous online learning and simulation. The course content was a product of data collected from a targeted needs assessment. The cognitive learning objectives were taught through the online modules. Four simulation sessions were used to teach procedural skills. Bedside teaching simultaneously occurred from critical care faculty during daily rounds. We assessed learning through a pre and post knowledge multiple choice question (MCQ) test. Faculty assessed learners by direct observation and review of clinical documentation. We evaluated learner reaction and comfort in critical practice by comparing pre and post surveys. RESULTS: All 7 NPs were satisfied with the course and found the format to work well with their clinical schedules. The course also improved their self-reported comfort in managing critically ill patients in a medical ICU. There was an increase in the mean group score from the pre-to the post-course MCQ (60% vs 73%). CONCLUSIONS: The COVID-19 Critical Care Course (CCCC) for NPs was implemented in our ICU to better prepare for an anticipated second surge. It focused on delivering practical knowledge and skills as learners cared for critically ill COVID-19 patients. In a short period of time, it engaged participants in active learning and allowed them to feel more confident in applying their education.

Bilateral Bilothorax: An Unusual Cause of Bilateral Exudative Pleural Effusion.

Bilothorax is an uncommon cause of exudative pleural effusion; the majority of reported cases are right-sided while a bilateral presentation is extremely rare. The majority of cases are secondary to biliary obstruction, an extension of hepatic infections, and iatrogenic complications following percutaneous procedures or surgical interventions. Imaging studies and a diagnostic pleural tap can confirm the diagnosis. Early recognition and complete drainage are important to prevent life-threatening complications, including empyema formation. We present a case of a 71-year-old female who developed bilateral bilothorax as a complication of gallstone pancreatitis.

3D-printing a 'family' of biomimetic models to explain armored grasping in syngnathid fishes.

Seahorses and pipehorses evolved at least two independent strategies for tail grasping, despite being armored with a heavy body plating. To help explain mechanical trade-offs associated with the different designs, we created a 'family' of 3D-printed models that mimic variations in the presence and size of their armored plates. We measured the performance of the biomimetic proxies across several mechanical metrics, representative of their protective and prehensile capacities. Our results show that the models mimicking the tails of seahorses are the best all-around performers, while those of the distal-most, prehensile region of pipehorses are more flexible, but less protected. The comparison also reveals that different adaptive strategies provide different task-specific performance advantages, which could be leveraged for the design of armored manipulators or other bio-inspired technologies.

3D-printing and mechanics of bio-inspired articulated and multi-material structures.

3D-printing technologies allow researchers to build simplified physical models of complex biological systems to more easily investigate their mechanics. In recent years, a number of 3D-printed structures inspired by the dermal armors of various fishes have been developed to study their multiple mechanical functionalities, including flexible protection, improved hydrodynamics, body support, or tail prehensility. Natural fish armors are generally classified according to their shape, material and structural properties as elasmoid scales, ganoid scales, placoid scales, carapace scutes, or bony plates. Each type of dermal armor forms distinct articulation patterns that facilitate different functional advantages. In this paper, we highlight recent studies that developed 3D-printed structures not only to inform the design and application of some articulated and multi-material structures, but also to explain the mechanics of the natural biological systems they mimic.