Swallowing Dynamics and Breathing-Swallowing Coordination Are Altered in Patients with Mild Cognitive Impairment

<b><i>Introduction:</i></b> Postinspiratory activity, which is essential for laryngeal closure during swallowing to prevent aspiration of food into the airways, is reduced in a mouse model of tauopathy. Therefore, we hypothesized that patients at the stage of mild cognitive impairment (MCI) exhibit alterations in swallowing dynamics and coordination between swallowing and breathing. <b><i>Methods:</i></b> We examined breathing-swallowing coordination in patients with MCI. Patients who scored ≥24 on the Mini-Mental State Examination and &#x3c;26 on the Japanese version of the Montreal Cognitive Assessment were recruited at Sumoto Itsuki Hospital. Parameters associated with breathing-swallowing coordination were assessed using a combination of two sensors: a respiratory flow sensor and a piezoelectric sensor attached to the skin surface of the anterior neck. <b><i>Results:</i></b> Nineteen patients met the criteria for MCI; 16 of these patients (79.5 ± 9.1 years old) scored &#x3c;3 on the 10-item Eating Assessment Tool and were enrolled in the study. Their data were compared with those of an age-matched elderly cohort (79.9 ± 2.9 years old). The frequencies of swallowing during inspiration and swallowing immediately followed by inspiration in patients with MCI were 6.9% and 9.6%, respectively; these frequencies were not significantly different from those of the age-matched elderly cohort. However, the timing of swallowing in the respiratory cycle was significantly delayed in the MCI patients, and both time from the onset to the peak of laryngeal elevation and the duration between the onset of rapid laryngeal elevation and the time when the larynx returned to the resting position were significantly lengthened in this group. <b><i>Conclusion:</i></b> At the stage of MCI, breathing-swallowing coordination has already started to decline.

Automatic Separation of Respiratory Flow from Motion in Thermal Videos for Infant Apnea Detection

Both Respiratory Flow (RF) and Respiratory Motion (RM) are visible in thermal recordings of infants. Monitoring these two signals usually requires landmark detection for the selection of a region of interest. Other approaches combine respiratory signals coming from both RF and RM, obtaining a Mixed Respiratory (MR) signal. The detection and classification of apneas, particularly common in preterm infants with low birth weight, would benefit from monitoring both RF and RM, or MR, signals. Therefore, we propose in this work an automatic RF pixel detector not based on facial/body landmarks. The method is based on the property of RF pixels in thermal videos, which are in areas with a smooth circular gradient. We defined 5 features combined with the use of a bank of Gabor filters that together allow selection of the RF pixels. The algorithm was tested on thermal recordings of 9 infants amounting to a total of 132 minutes acquired in a neonatal ward. On average the percentage of correctly identified RF pixels was 84%. Obstructive Apneas (OAs) were simulated as a proof of concept to prove the advantage in monitoring the RF signal compared to the MR signal. The sensitivity in the simulated OA detection improved for the RF signal reaching 73% against the 23% of the MR signal. Overall, the method yielded promising results, although the positioning and number of cameras used could be further optimized for optimal RF visibility.

Validation of a new wearable device for type 3 sleep test without flowmeter

Background Ventilation monitoring during sleep is performed by sleep test instrumentation that is uncomfortable for the patients due to the presence of the flowmeter. The objective of this study was to evaluate if an innovative type 3 wearable system, the X10X and X10Y, is able to correctly detect events of apnea and hypopnea and to classify the severity of sleep apnea without the use of a flowmeter. Methods 40 patients with sleep disordered breathing were analyzed by continuous and simultaneous recording of X10X and X10Y and another certified type 3 system, SOMNOtouch, used for comparison. Evaluation was performed in terms of quality of respiratory signals (scores from 1, lowest, to 5, highest), duration and classification of apneas, as well as identification and duration of hypopneas. Results 580 periods were evaluated. Mean quality assigned score was 3.37±1.42 and 3.25±1.35 for X10X and X10Y and SOMNOtouch, respectively. The agreement between the two systems was evaluated with grades 4 and 5 in 383 out of 580 cases. A high correlation (r2 = 0.921; p<0.001) was found between the AHI indexes obtained from the two systems. X10X and X10Y devices were able to correctly classify 72.3% of the obstructive apneas, 81% of the central apneas, 61.3% of the hypopneas, and 64.6% of the mixed apneas when compared to SOMNOtouch device. Conclusion The X10X and X10Y devices are able to provide a correct grading of sleep respiratory disorders without the need of a nasal cannula for respiratory flow measurement and can be considered as a type 3 sleep test device for screening tests.

Measuring the mechanical input impedance of the respiratory system with breath-driven flow oscillations

The technique of oscillometry for measuring the mechanical input impedance of the respiratory system is gaining traction as a clinical diagnostic tool, but the portability of existing commercially available devices is limited by the size and weight of oscillator motors and power supplies. We show that impedance can be measured by oscillations in mouth pressure and flow generated by mucus-clearing devices that are powered by the subject’s own respiratory flow. This principle might thus be employed in lightweight ambulatory oscillometry devices.

Aerial Transmission of the SARS-CoV-2 Virus through Environmental E-Cigarette Aerosols: Implications for Public Policies

We discuss the implications of possible contagion of COVID-19 through e-cigarette aerosol (ECA) for prevention and mitigation strategies during the current pandemic. This is a relevant issue when millions of vapers (and smokers) must remain under indoor confinement and/or share public outdoor spaces with non-users. The fact that the respiratory flow associated with vaping is visible (as opposed to other respiratory activities) clearly delineates a safety distance of 1–2 m along the exhaled jet to prevent direct exposure. Vaping is a relatively infrequent and intermittent respiratory activity for which we infer a mean emission rate of 79.82 droplets per puff (6–200, standard deviation 74.66) comparable to mouth breathing, it adds into shared indoor spaces (home and restaurant scenarios) a 1% extra risk of indirect COVID-19 contagion with respect to a “control case” of existing unavoidable risk from continuous breathing. As a comparative reference, this added relative risk increases to 44–176% for speaking 6–24 min per hour and 260% for coughing every 2 min. Mechanical ventilation decreases absolute emission levels but keeps the same relative risks. As long as direct exposure to the visible exhaled jet is avoided, wearing of face masks effectively protects bystanders and keeps risk estimates very low. As a consequence, protection from possible COVID-19 contagion through vaping emissions does not require extra interventions besides the standard recommendations to the general population: keeping a social separation distance of 2 m and wearing of face masks.

Acute respiratory flow restriction affects average power, but not heart rate and subjective perceived exertion in healthy women

ABSTRACT This study aims to verify the effect of the restriction of the ventilatory flow on HR, RPE, and power during HIT-test performed by healthy women. The participants (n=8) underwent HIT-test without and with ventilatory flow restriction. HR, power, and RPE was measured. HRpost showed no significant difference between conditions (p=0,053). The average power presented higher values in the condition without the restriction of ventilatory flow (619,51±144,33W; 565,99±108,43W; p=0,001), but without differences in the fatigue index (p=0,383). In both conditions, increases in RPE were observed during the efforts (p<0,001). It is concluded that HR and RPE did not suffer acute effects from the restriction of ventilatory flow; however, the average power is decreased during HIT-test.

Como realizar a análise tridimensional das vias aéreas superiores em pacientes ortodônticos?

The upper airways (UA) are influenced by the growth and development of the craniofacial complex and any alteration in the maxillary bones during orthodontic treatment can narrow or increase the size of the pharyngeal spaces. The three-dimensional analysis of the volume and the minimum axial area of the respective sub-spaces is beneficial for case planning as it allows the identification of possible physical barriers that compromise the air passage and the respiratory flow, besides being an auxiliary diagnostic method for disorders related to this function. The request for cone-beam computed tomography (CBCT) is necessary for the correct digital evaluation with the appropriate protocols for the acquisition and reconstruction of the image exams, calibration of the methodology, and standardization of their analysis. The objective of this work is to demystify the specific step-by-step analysis in the Dolphin Imaging® software and to describe the technical and anatomical factors for delimiting the spaces corresponding to the UA. To illustrate this protocol, CBCT of a patient with Angle Class II malocclusion, first division were analyzed before the installation (T1) of a mandibular thruster (fixed cemented Herbst appliance with dental anchorage) and after 12 months of treatment (T2). From the measurement of the spaces corresponding to VAS, comparing the two treatment times, it was possible to analyze the changes in the pharyngeal space after the use of mandibular thruster and to highlight the importance of the three-dimensional assessment of the air dimension for individualized orthodontic planning.

Changes in Inspiratory and Expiratory Flow Rates with Sustained Hand Grip and their Correlation with Fat Free Mass Index in Healthy Young Adults

Introduction: Aerobic exercises which are isotonic in nature have been proved to be beneficial in a number of cardiovascular and lifestyle diseases. But the effect of isometric exercises on cardiovascular and respiratory system is not fully evaluated. Existing literature on effect of isometric exercise on respiratory flow parameters are scanty and needs to be studied. Further, the impact of muscle mass on respiratory flow parameters need to be evaluated. Aim: To investigate the change in respiratory flow parameters (Peak Inspiratory Flow (PIF), Maximal Inspiratory Flow (MIF) 50, Peak Expiratory Flow (PEF), Maximum Expiratory Flow (MEF) 25-75, MEF 25, MEF 50 and MEF 75) in response to Sustained hand grip exercise and to find out any correlation between these flow parameters and Fat Free Mass Index (FFMI). Materials and Methods: A cross-sectional study was conducted at Department of Physiology, MKCG Medical College, Berhampur University, Odisha between October 2011 and August 2014. A total of 150 healthy volunteers aged between 17 to 25 years were included in the study. Anthropometric measurements were recorded using standardised instruments. Body fat percentage was measured by Bioelectric Impedance Analysis technique and then Fat Free Mass (FFM) and FFMI were calculated using standard formulae. Respiratory Flow parameters were assessed using Flow handy Spirometer as per the American Thoracic Society/European Respiratory Society (ATS/ERS) guidelines. Sustained hand grip exercise was performed with Physilab Grip Dynamometer. IBM SPSS Statistics Version 24.0, was used for statistical analysis. Paired sample t-test was used to compare lung volumes at baseline and after 3 minutes of sustained hand grip exercise. The p-value <0.05 was considered statistically significant. Karl Pearson Correlation coefficient was used to study the linear relationship between FFMI and various inspiratory and expiratory flow rates. Results: The mean values of all respiratory flow parameters under study decreased at 3 minutes of sustained hand grip exercise as compared to baseline values. This change was statistically significant for PEF (p-value 0.012), MEF 25-75 (p-value 0.041), MEF 50 (p-value 0.001), MEF 75 (p-value 0.012) and MIF50 (p-value 0.004) (p<0.05). All the flow rates studied except MEF 25 showed significant positive correlation with FFMI (r-values between 0.231 to 0.380, p<0.05) but the strength of association was low. Conclusion: There was a statistically significant reduction in both inspiratory and expiratory flow parameters with isometric sustained hand grip exercise. So, isometric exercises should be avoided in patients with obstructive airway diseases. But muscle mass should be improved for better ventilation as authors observed a positive correlation between FFMI and respiratory flow rates.