Dissertations / Theses on the topic 'High Frequency Percussive Ventilation'

2009/2010
The thesis describes the study on the characterization of the percussive ventilator; the activities have been carried out in cooperation with the “D.A.I. di Medicina Perioperatoria, Terapia Intensiva ed Emergenza - UCO di Anestesia, Rianimazione e Terapia Antalgica dell'Azienda Mista Universitaria - Ospedaliera di Trieste”. The first chapter describes the physiology of the respiratory system and the classical models presented in literature, the second chapter illustrates the main modes of mechanical ventilation, particularly in the percussive ventilation. The third chapter describes the classical laboratory equipment for the measurement of breathing. The fourth chapter examines the state of the art of methods and instruments for the analysis of respiratory parameters. The fifth chapter discusses the instruments for measuring respiratory parameters, developed in the biomedical laboratory of the DEEI of University of Trieste. The sixth chapter contains a detailed study on the characterization of the percussive ventilator: the model, the method for estimating parameters, the system tests and the results. Particularly, the ability to monitor respiratory parameters by using the instrument developed avoids the volutrauma (alveolar-capillary permeability increase owing to excessive distension of the lung) during controlled ventilation. The instrument also allows to accurately estimate the lung elastance, determining factor of the volume distribution in the used model. At the conclusion of the work, the seventh chapter summarizes the results from the study of the volumes distribution in the two-compartment model of the lung conditioned to percussive ventilation.
XXIII Ciclo
1965

2013/2014
High Frequency Percussive Ventilation (HFPV) is a non-conventional ventilatory modality which has proven highly effective in patients with severe gas exchange impairment. However, at the present time, HFPV ventilator provides only airway pressure measurement. The airway pressure measurements and gas exchange analysis are currently the only parameters that guide the physician during the HFPV ventilator setup and treatment monitoring. The evaluation of respiratory system resistance and compliance parameters in patients undergoing mechanical ventilation is used for lung dysfunctions detection, ventilation setup and treatment effect evaluation. Furthermore, the pressure measured by ventilator represents the sum of the endotracheal tube pressure drop and the tracheal pressure. From the clinical point of view, it is very important to take into account the real amount of pressure dissipated by endotracheal tube to avoid lung injury. HFPV is pressure controlled logic ventilation, thus hypoventilation and hyperventilation cases are possible because of tidal volume variations in function of pulmonary and endotracheal tube impedance. This thesis offers a new approach for HFPV ventilator setup in accordance with protective ventilatory strategy and optimization of alveolar recruitment using estimation of the respiratory mechanics parameters and endotracheal pressure drop. Respiratory system resistance and compliance parameters were estimated, firstly in vitro and successively in patients undergoing HFPV, applying least squares regression on Dorkin high frequency model starting from measured respiratory signals. The Blasius model was identified as the most adequate to estimate pressure drop across the endotracheal tube during HFPV. Beside measurement device was developed in order to measure respiratory parameters in patients undergoing HFPV. The possibility to tailor HFPV ventilator setup, using respiratory signals measurement and estimation of respiratory system resistance, compliance and endotracheal tube pressure drop, provided by this thesis, opens a new prospective to this particular ventilatory strategy, improving its beneficial effects and minimizing ventilator-induced lung damage.
XXVII Ciclo
1981

2012/2013
The use of High Frequency Percussive Ventilation (HFPV) is still debated although this type of non-conventional ventilation has proven effective and safe in patients with acute respiratory failure. In the clinical practice, HFPV is not an intuitive ventilatory modality and the absence of real-time delivered volume monitoring produces disaffection among the physicians. Avoiding the "volutrauma" is the cornerstone of the "protective ventilation strategy", which assumes a constant monitoring of inspiratory volume delivered to the patient. Currently the system capable of delivering HFPV is the VDR-4® (Volumetric Diffusive Respirator), which provides only analog airway pressure waveform and digital output of peak and the mean airway pressure. The latter is involved in the determination of oxygenation and hemodynamics, irrespective of the mode of ventilation. At the present time, the mean airway pressure, together with gas exchange analysis, are the only parameters that indirectly guide the physician in assessing the clinical effectiveness of HFPV. Till now, flow, volume and pressure curves generated by HFPV have never been studied in relation to the specific patients respiratory mechanics. The real-time examination of these parameters could allow the physicians to analyze and understand elements of respiratory system mechanics as compliance (Crs), resistance (Rrs), inertance (Irs) and of patient-ventilator interaction. The mechanical effects are complex and result from interactions between ventilator settings and patient’s respiratory system impedance. The aim of this doctoral thesis was to acquire and study volume and respiratory parameters during HFPV in order to explain this complex patients-machine interaction and transfer the results in clinical practice.
XXVI Ciclo
1959

Ventilation by high-frequency body-surface oscillation (HFBSO) was studied in normal rabbits. Adequate ventilation and acceptable gas exchange took place during HFBSO from 3 to 15 Hz. The tidal volume required to maintain a normocapnic state was established at each frequency studied. Using catheter-tip micromanometers inserted in the esophagus or the superior vena cava, new techniques to measure high-frequency intrathoracic pressure oscillations were developed. Using a gamma-function to fit the thermodilution curve, a new technique was developed to measure the cardiac output in small animals. No detrimental hemodynamic effect was found during HFBSO used either for normocapnic ventilation or with large pressure oscillations (30 cm H$ sb{ rm 2}$O) in the body chamber. Finally, during normocapnic ventilation by HFBSO in normal rabbits, the mechanical behavior of the respiratory system was characterized using transfer impedances.

Physiologic and Extracorporeal Shock Wave Lithotripsy (ESWL) data were collected before, during and after ESWL from four patient groups employing different anesthetic techniques (epidural anesthesia, general anesthesia with low-volume conventional mechanical ventilation or with unsynchronized high frequency jet ventilation (HFJV) or with HFJV synchronized to the heart rate). The primary goal was to determine if synchronized HFJV had any beneficial effects. A synchronization unit was fabricated that triggered one HFJV breath, per heart beat, delivered 30 milliseconds after the shock wave. This allowed only expiratory motion during shock wave administration. Results were analyzed using one-way analysis of variance, Students t-tests and chi-square tests with significance at p 0.05. Results showed that renal stone excursion was significantly less in HFJV groups and that significantly more patients required re-treatment in non-HFJV groups. No results indicated that synchronizing HFJV had any further benefits than unsynchronized HFJV.

COMPARISON OF ALBUTEROL DELIVERY BETWEEN HIGH FREQUENCY OSCILLATORY VENTILATION AND CONVENTIONAL MECHANICAL VENTILATION IN A SIMULATED ADULT LUNG MODEL USING DIFFERENT COMPLIANCE LEVELS By Waleed A. Alzahrani, BSRT BACKGROUND: Delivery of aerosol by pMDI has been described with conventional mechanical ventilation (CMV) but not with high frequency oscillatory ventilation (HFOV). The purpose of this study was to compare aerosol delivery to a simulated 75 kg adult with low compliance during both CMV and HFOV. Since actuation of pMDI with inspiration is not feasible with HFOV, we investigated the impact of actuation timing only during CMV. METHOD: CMV (Respironics Esprit) and HFOV (Sensor Medics 3100B) ventilators with passover humidifiers and heated circuits were connected by 8 mm ID ETT and filter (Respirgard II, Vital Signs) to a test lung (TTL) with compliance settings of 20 and 40 ml/cm H2O in order to simulate a non compliant lung. Settings for CMV (VT 6 ml/kg, I:E 1:1, PEEP 20 cm H2O, and RR 25/min), and HFOV (RR 5 Hz, IT 33%, ∆P 80 cm H2O and mPaw 35 cm H2O) were used, with similar mPaw on CMV and HFOV. Parameters were selected based on ARDSnet protective lung strategy (Fessler and Hess, Respiratory Care 2007) Eight actuations of albuterol from pMDI (ProAir HFA, Teva Medical) with double nozzle small volume spacer (Mini Spacer, Thayer Medical) placed between the “Y” adapter and ETT at more than 15 sec intervals for each condition (n=3). During CMV, pMDI actuations were synchronized (SYNC) with the start of inspiration at more than 15 s, and nonsynchronized (NONSYNC) with actuations at 15 s intervals. Drug was eluted from the filter and analyzed by spectrophotometry (276 nm). Repeated measures ANOVA, pairwise comparisons and independent t- tests were performed at the significance level of 0.05. RESULTS: In all cases, aerosol delivery was greater with HFOV than CMV (p<0.05). Synchronizing pMDI actuations with the beginning of inspiration increased aerosol deposition significantly at compliance levels 20 ml/cm H2O and 40 ml/cm H2O (p=0.011 and p=0.02, respectively). Lung compliance and aerosol delivery are directly related. Increasing lung compliance to 40 ml/cmH2O improved aerosol delivery during CMV and HFOV (p<0.05). CONCLUSION: Albuterol deposition with pMDI was more than two fold greater with HFOV than CMV in this in-vitro lung model. Changing lung compliance has almost 2 fold impact on aerosol delivery during both modes of ventilation. Furthermore, synchronizing pMDI actuations during CMV improved aerosol delivery up to 4 fold.

Clinical concerns exist regarding the delivered tidal volume (Vt) during high-frequency oscillatory ventilation (HFOV). HFOV is increasingly being used as a lung protective mode of ventilation for patients with Adult Respiratory Distress Syndrome (ARDS), but caution must be utilized. The purpose of this study was to investigate the effect of airway compliance on Vt delivered by HFOV to the adult patient. Method: An in vitro model was used to simulate an adult passive patient with ARDS, using a high fidelity breathing simulator (ASL 5000, IngMar Medical). The simulation included independent lung ventilation with a fixed resistance and adjustable compliance for each lung. Compliances of 10, 15, 20 and 25 ml/cmH2O were used and resistance (Raw) was fixed at 15 cm H2O/L/s. The ventilator SensorMedics 3100B (Cardinal Health, Dublin, Ohio) was set to a fixed power setting of 6.0, insp-% of 33%, bias flow =30 L/min, and 50% oxygen and Hz of 5.0 (n=5) for each compliance setting. Mean airway pressure (mPaw) and amplitude (AMP) varied as the compliance changes were made. Approximately 250 breaths were recorded at each compliance setting and the data was collected via the host computer and transferred to a log to be analyzed by SPSS v. 10. Data Analysis: The data analysis was performed using SPSS v. 10 to determine the statistical significance of the delivered Vt with different compliances, different AMP and a fixed power setting. A probability of (p < 0.05) was accepted as statistically significant. Results: The average delivered Vt with each compliance was 124.181 mL (range of 116.4276 mL and 132.6637 mL) and average AMP of 84.85 cm/H2O (range 82.0 cm/H2O and 88.0801 cm/H2O) n=5. There was an inverse relationship between Vt and AMP at a fixed power of 6.0. As compliance improved Vt increased and there was a corresponding decrease in AMP. The one-way ANOVA test showed that there were significant differences between the delivered tidal volume and AMP at a fixed power setting. When the post hoc Bonferroni test was used the data showed significant differences between AMP achieved with each compliance change and a fixed power of 6.0. When the post hoc Bonferroni test was used the data showed significant differences between Vt delivered with each compliance change and a fixed power setting of 6.0. Conclusion: Vt is not constant during HFOV. Compliance is one determinant of Vt in adults with ARDS during HFOV. AMP and Vt are inversely related during HFOV at a fixed power setting and improving compliance.

Concerns exist regarding the ability of HFOV to provide the needed lung protective ventilation for adult patients with ARDS. HFOV is increasingly being used as a lung protecting ventilation mode even if some of its protective attributes may be lost as the airway resistance (Raw) increases or decreases. In fact, in cases of shifting air resistance, HFOV may have caused lung injury. PURPOSE: The purpose of this study was to investigate the effect of airway resistance on tidal volume (Vt) delivered by HFOV to adult patients. Also, the study intended to determine direction for volume change when resistance increases or decreases. METHODS: An in vitro model was used to simulate an adult passive patient with ARDS using a breathing simulator (Active Servo Lung 5000, Ingmar Medical, Pittsburgh, PA, USA). Adjustable resistance and compliance for each lung was used. The resistance levels of 15, 30, 45 (cm H2O/L/sec) were used for upper and lower Raw and CL was fixed at 40 mL/cm H2O. The ventilator (Sensormedics 3100B) was set to MAP = 35 cm H2O, to insp-time of 33%, to bias flow =30 L/min, to delta-P of 80, and to 50% oxygen. Vt was recorded (n=3) for each Raw, and the data was collected on the host computer. Approximately 200-250 breaths of data for each Raw were captured via the ASL software and then converted to Excel for analysis. An average of 80 breathes (following the steady Vt level) was used in each analysis. DATA ANALYSIS: The data analysis was performed with one way ANOVA and with a post hoc Bonferroni test in order to determine the statistical significance of the delivered Vt with each Raw. A probability of (p < 0.05) was accepted as statistically significant. RESULTS: The descriptive statistics of the average delivered Vt with regard to each Raw (15, 30, 45 cm H2O/L/sec) were the number of experiments (n=3), mean Vt (93.52, 89.09, 85.99 mL), and standard deviations (SD) (1.38, 1.11, 1.10) respectively. There was an inverse relationship between tidal volume and airway resistance during HFOV. With all other variables kept constant, higher resistance caused less volume, whereas lower resistance caused more volume. The one-way ANOVA test showed that there were significant differences between the delivered tidal volumes. When the post hoc Bonferroni test was used, the data showed significant differences between airway resistances of 15 cm H2O/L/sec and 30 cm H2O/L/sec and between 15 cm H2O/L/sec and 45 cm H2O/L/sec. In contrast, no significant differences were found between airway resistances of 30 cm H2O/L/sec and 45 cm H2O/L/sec. CONCLUSION: Vt is not constant during HFOV. Airway resistance is one of the determinants of delivered tidal volume in adults with ARDS during HFOV. Airway resistance should be an important factor in ventilator management and in clinical experiments of patients on HFOV. Without a proper Vt measurement device HFOV should not be used as lung protective ventilation for adult patients with ARDS.

Background: Ventilatory pressures should target the range between the upper and lower inflection point of the pressure volume curve in order to avoid atelecto- and volutrauma. During high-frequency oscillatory ventilation (HFOV), this range is difficult to determine. Quadrant impedance measurement (QIM) has recently been shown to allow accurate and precise measurement of lung volume changes during conventional mechanical ventilation. Objectives: To investigate if QIM can be used to determine a static pressure-residual impedance curve during a recruitment-derecruitment manoeuvre on HFOV and to monitor the time course of alveolar recruitment after changing mean airway pressure (MAP). Methods: An incremental and decremental MAP trial (6 cm H₂O to 27 cm H₂O) was conducted in five surfactantdepleted newborn piglets during HFOV. Ventilatory, gas exchange and haemodynamic parameters were recorded. Continuous measurement of thoracic impedance change was performed. Results: Mean residual impedance (RI) increased with each stepwise increase of MAP resulting in a total mean increase of +26.5% (±4.0) at the highest MAP (27 cm H₂O) compared to baseline ventilation at 6 cm H₂O. Upon decreasing MAP levels, RI fell more slowly compared to its ascent; 83.4% (±19.1) and 84.8% (±16.4) of impedance changes occurred in the first 5 min after an increase or decrease in airway pressure, respectively. Conclusions: QIM could be used for continuous monitoring of thoracic impedance and determination of the pressure-RI curve during HFOV. The method could prove to be a promising bedside method for the monitoring of lung recruitment during HFOV in the future.

Laparoscopic liver surgery is complicated due to the structure of this organ with open sinusoids. A serious disadvantage is the risk of gas embolism (GE) due to CO2 pneumoperitoneum. CO2 can enter the vascular system through a wounded vein. A common opinion is that gas fluxes along a pressure gradient, e.g. CVP-intra abdominal pressure (IAP). The occurrence of GE could also be eased by entrainment, a ‘Venturi-like’ effect, due to cyclic differences in thoracic pressure and blood flow caused by mechanical ventilation at normal frequency. The aims of these studies were to survey, in a porcine model, the influence on respiratory and haemodynamic variables by GE, to determine at what frequency, severity and duration GE occurs during laparoscopic liver resection (LLR) and whether there are methods to influence the occurrence or severity of GE. Pulmonary and circulatory variables were monitored and measured as well as continuous blood gas monitoring. Transoesophageal echocardiogram was used to identify GE and, according to the amount of bubbles in the right outflow tract of the heart, GE was graded as 0, 1 and 2. Pneumoperitoneum was created by using CO2and IAP was set to 16 mm Hg. A single bolus dose of CO2 influenced respiratory and haemodynamic variables for at least 4 h. During LLR GE occurred in 65-70% of the animals, of which the more serious caused negative influence on cardiopulmonary variables. Elevated PEEP (15 cm H2O) increased CVP but GE occurred irrespective if CVP was lower than or exceeded IAP. In two last studies, a hepatic vein was cut and left open for 3 m before it was clipped. Interestingly, no signs of GE were seen despite an open vein and IAP > CVP in 8 of 20 animals. In the last study high frequency jet ventilation was used in order to minimise the risk of entrainment. The duration of GE was shortened. The occurrence of GE seemed to be influenced by several different factors. The physiological reaction of a GE is impossible to predict for a specific patient, and depends among other factors on comorbidity, and amount, site and entrance rate of GE.

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Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)
A Síndrome do Desconforto Respiratório Agudo (SDRA) cursa com alta morbi-mortalidade apesar dos avanços no entendimento de sua fisiopatologia e tratamento. A terapia ventilatória baseia-se na proteção pulmonar, sendo a ventilação oscilatória de alta frequência (VOAF) uma opção de método protetor. A posição prona (PP) é terapia adjuvante que possibilita homogeneização da distribuição do volume corrente (VC) e promove recrutamento alveolar. O objetivo do estudo foi investigar o efeito da posição prona associada à VOAF e ventilação mecânica convencional (VMC) protetora sobre a oxigenação, inflamação, dano oxidativo e histologia pulmonares, comparando-a à posição supina em ambos os modos ventilatórios. Foram instrumentados 75 coelhos com traqueostomia e acessos vasculares. A lesão pulmonar aguda (LPA) foi induzida por lavagem traqueal de salina aquecida (30mL/Kg, 38°C). Os animais foram então aleatorizados em cinco grupos (n=15): 1) GC (Controle): animais sadios em VMC protetora basal; 2) GVMS: animais com LPA em VMC protetora e posição supina; 3) GVMP: animais com LPA em VMC protetora e posição prona; 4) GVAFS: animais com LPA em VOAF e posição supina; 5) GVAFP: animais com LPA em VOAF e posição prona. Após, foram submetidos a quatro horas de VMC protetora (modo pressão regulada-volume controlado, PEEP 10 cmH2O, VC 6mL/kg, Ti 0,5s, FR 40 rpm e FiO2 1) ou VOAF (MAP 15 mmHg, FR 10Hz, amplitude 22 e FiO2 1). O nível de significância foi de 5%. Após a indução, os grupos apresentaram comportamentos semelhantes, com diminuição da relação PaO2/FiO2 e da complacência pulmonar, e aumento do índice de oxigenação (IO) e da pressão média de via aérea (p > 0,05). Ao final do experimento, houve aumento da PaO2/FiO2 nos grupos VOAF comparado aos grupos em VMC (p < 0,05). Houve queda do IO para os grupos em VOAF comparados ao GVMS (p < 0,05), porém o GVMP não diferiu deles (p > 0,05). Não houve diferença estatística quanto à contagem de células polimorfonucleares no lavado broncoalveolar (BAL) nos grupos com LPA. Não houve diferença estatística entre os grupos com lesão para a medida de TNF-alfa no plasma e para sua expressão gênica em tecido pulmonar. Entretanto, a medida de TNF-alfa no lavado broncoalveolar (BAL) e no tecido pulmonar no grupo GVMP foi menor, assemelhando-se ao controle (p > 0,05). Não houve diferença no dano oxidativo avaliado no tecido pulmonar entre os grupos (p > 0,05) e, também, na comparação entre regiões ventral e dorsal dos pulmões. O escore de lesão histológica foi menor nos grupos em VOAF, efeito potencializado no grupo em prona quando comparado aos grupos em VMC (GC = GVAFP < GVMS = GVMP), sem diferença na regionalização pulmonar. Concluimos que, em modelo de LPA por lavagem alveolar com salina aquecida em coelhos: a VOAF melhora a oxigenação quando comparados à VMC; na VMC, a PP atenua a lesão inflamatória avaliada pela medida de TNF-alfa no BAL e tecido pulmonar; os modos ventilatórios e as posições não modificam o grau de estresse oxidativo quando avaliados pelo método de malondialdeído; a VOAF melhora o escore histopatológico de lesão pulmonar, independemente da posição, mas a associação de VOAF e PP atenua a lesão histopatológica quando comparada com a VMC protetora, seja em posição prona ou supina.
Acute Respiratory Distress Syndrome (ARDS) presents with high morbidity and mortality despite advances in the understanding of its pathophysiology and treatment. Ventilatory therapy is based on the intention of injuring less, with high frequency oscillatory ventilation (HFOV) being a protective method option. Prone position (PP) is an adjuvant therapy that enables homogenization of volume tidal (VT) distribution and promotes alveolar recruitment. The aim of this study was to investigate the effects of prone position associated with HFOV and protective conventional mechanical ventilation (CMV) on oxygenation and lung inflammation, oxidative damage and histology, comparing it with the supine position in both ventilatory modes. Seventy five rabbits were submitted to tracheostomy and vascular accesses. ALI was induced by tracheal infusion of heated saline (30mL/kg, 38° C). The subjects were then ramdomized in five groups (n=15): 1) CG (Control): healthy animals in basal protective CMV; 2) MVSG: animals with ALI in protective CMV and supine position; 3) MVPG animals with ALI in protective CMV and prone position; 4) HFSG: animals with ALI in HFOV and supine position; 5) HFPG: animals with ALI in HFOV and prone position. After that, they were submitted to four hours of protective VMC (PRV mode, PEEP 10 cmH2O, VC 6ml/kg, Ti 0,5s, FR=40 rpm and FiO2 1) or HFOV (MAP 15 mmHg, FR 10 Hz, amplitude 22 and FiO2 1). The level of significance was 5%. After induction, the groups presented similar behaviors, with a decrease in the PaO2/FiO2 ratio and lung compliance, and an increase in oxygenation index (OI) and mean airway pressure (p > 0.05). At the end of experimental time, PaO2/FiO2 increased in the HFOV groups compared to the CMV groups (p < 0.05). There was a decrease in OI for HFOV groups compared to MVSG (p < 0.05), but MVPG did not differ from them (p > 0.05). There was no statistically significant difference in polymorphonuclear cell counts in bronchoalveolar lavage (BAL) in the groups with ALI. There was no difference between ALI groups regarding the TNF-alfa dosage in plasma and its gene expression in lung tissue. However, TNF-alpha measurement in BAL and in lung tissue was smaller, resembling control (p > 0.05). There was no difference in the oxidative damage assessed in the lung tissue between the groups (p > 0.05), nor between the lung regions. The histological damage score was lower in the HFOV groups, potentiated effect in the prone group when compared to the CMV groups (CG = HFPG < MVSG = MVPG), no difference in pulmonary regionalization. We conclude that, in the model of ALI induced by alveolar lavage with heated saline in rabbits: HFOV improves oxygenation if compared to CMV; PP in CMV attenuates lung inflammation, evaluated by TNF-alfa dosage in BAL and in lung tissue; ventilatory modes and positions don’t modify the oxidative stress whan evaluated by malondialdehyde method; HFOV improves histopathological lung lesion score, regardless of position, but HFOV and prone position association attenuates histopathological injury compared to protective CMV, either in the prone or supine positions.
FAPESP: 2010/06242-8

Introduction: The use of high frequency oscillatory ventilation is increasing in treatment ofacute respiratory distress syndrome over the past decade. The technique of HFOV of ventilatingthe lungs at volumes less than the anatomical dead space calms the clinical concerns surroundingventilating stiff ARDS lungs with high pressures and volumes. This largely reduces theprobability of barotraumas and/or atelectrauma. Purpose: The study was on an in vitro bench model that answered the following researchquestions: 1. The effect of three inline closed suction adapters on delivered tidal volume duringHFOV with varying lung compliance 2. The effect of varying compliance on the amplitudedelivered by HFOV; and 3. The effect of compliance on tidal volume delivered by HFOV. Method: An in vitro bench model using high fidelity breathing simulator (ASL 5000, IngMarMedical) simulating an adult patient with ARDS was set up with 3100B SensorMedic highfrequency ventilator. The simulation included varying the compliance for each lung at 50, 40, 30and 20cmH2O while maintaining fixed resistance of 15 cmH2O/L/sec. The ventilator was set tothe following parameters: power of 6, frequency (f) of 5, inspiratory time (Ti) of 33%, bias flow(BF) of 30 LPM and oxygen concentration of 50%. The breathing simulator was connected withthe high frequency ventilator using a standard HFOV circuit and a size 8.0mm of endotrachealtube. Fourteen French Kimberly Clark suction catheters (with T and Elbow adapters) and Air-Life suction catheters (Y adapter) were placed in-line with the circuit successively to carry outthe study. Each run lasted for 1 minute after achieving stable state conditions. Thisapproximated to 300 breaths. The data was collected from the stimulator and stored by the hostcomputer. Data Analysis: The data was analyzed using SPSS v.11 to determine the statistical significance.A probability value (P value) of ≤ 0.001 was considered to be statistically significant. Results: The data analysis showed that Air-Life Y-adapter suction catheters caused the least lostin tidal volume when placed in line with HFOV and hence proved to be the most efficient. Thestudy also showed a direct relationship between amplitude and lung compliance i.e. an increasein lung compliance caused an associated increase in amplitude (power setting remainingunaltered). Lastly, the study did not show a statistically significant change in tidal volume withchanges in lung compliance. Future studies may be required to further evaluate the clinicalsignificance of the same. Conclusion:1. Many factors affect delivery of tidal volume during high frequency ventilation and thus it isnot constant. Choice of in-line suction system to be placed in line is one of the determinants ofthe same.2. Lung compliance changes lead to associated changes in amplitude delivery by HFOV. Thisshould be adjusted as patient condition improves by altering the power settings to ensure optimalventilation and to avoid trauma to the lungs.

Introdução: A Síndrome do Desconforto Respiratório Agudo (SDRA) apresenta alta incidência e mortalidade em pacientes de terapia intensiva. A ventilação mecânica é o principal suporte para os pacientes que apresentam-se com SDRA, entretanto ainda existe muito debate sobre a melhor estratégia ventilatória a ser adotada, pois a ventilação mecânica pode ser lesiva aos pulmões e aumentar a mortalidade se mal ajustada. Um dos principais mecanismos de lesão pulmonar induzida pela ventilação é o uso de volumes correntes altos, havendo evidência na literatura que a utilização de volumes correntes menores fornece uma ventilação dita protetora, a qual aumenta a probabilidade de sobrevivência. Objetivo: Explorar se uma estratégia ventilatória de alta frequência com pressão positiva (HFPPV) realizada através de um ventilador mecânico convencional (Servo-300) é capaz de permitir uma maior redução do volume corrente e estabilização da PaCO2 em um modelo de SDRA severa, inicialmente ventilado com uma estratégia protetora. Métodos: Estudo prospectivo, experimental que utilizou oito porcos que foram submetidos a uma lesão pulmonar através de lavagem pulmonar com soro fisiológico e ventilação mecânica lesiva. Em seguida, os animais foram ventilados com um volume corrente de 6 mL/kg, seguido de uma randomização de sequências diferentes de frequências respiratórias (30, 60, 60 com pausa inspiratória de 10 e 30%, 90, 120, 150, 60 com manobra de recrutamento alveolar mais titulação da PEEP e HFOV com 5 Hertz), até obter estabilização da PaCO2 entre 57 63 mmHg por 30 minutos. O ventilador Servo-300 foi utilizado para HFPPV e o ventilador SensorMedics 3100B utilizado para fornecer a ventilação oscilatória de alta frequência (HFOV). Dados são apresentados como mediana [P25th,P75th]. Principais Resultados: O peso dos animais foi de 34 [29,36] kg. Após a lesão pulmonar, a relação P/F, o shunt pulmonar e a complacência estática dos animais ficaram em 92 [63,118] mmHg, 26 [17,31] % e 11 [8,14] mL/cmH2O respectivamente. O PEEP total usado foi de 14 [10,17] cmH2O durante o experimento. Da frequência respiratória de 35 (e com volume corrente de 6 mL/kg) até a frequência ventilatória de 150 rpm, a PaCO2 foi 81 [78,92] mmHg para 60 [58,63] mmHg (P=0.001), o volume corrente (VT) progressivamente caiu de 6.1 [5.9,6.2] para 3.8 [3.7,4.2] mL/kg (P<0.001), a pressão de platô de 29 [26,30] para 27 [25,29] cmH2O (P=0.306) respectivamente. Não houve nenhum comprometimento hemodinâmico ou da oxigenação, enquanto os animais utilizaram a FiO2 = 1. Conclusões: Utilizando-se de uma ventilação mecânica protetora, a estratégia de HFPPV realizada com um ventilador mecânico convencional em um modelo animal de SDRA severa permitiu maior redução do volume corrente, bem como da pressão de platô. Esta estratégia também permitiu a manutenção de PaCO2 em níveis clinicamente aceitáveis
Introduction: Acute respiratory distress syndrome (ARDS) has a high incidence and mortality between critical ill patients. The mechanical ventilation is the most important support for these patients with ARDS. However, until now there is an important debate about how is the best ventilatory strategy to use, because the mechanical ventilation if not well set can cause lung injury and increase mortality. The use of high tidal volume is one of the most important mechanics of ventilation induced lung injury and there is evidence in the literature that using low tidal volume is a protective ventilation with better survival. Objective: To explore if high frequency positive pressure ventilation (HFPPV) delivered by a conventional ventilator (Servo-300) is able to allow further tidal volume reductions and to stabilize PaCO2 in a severe acute respiratory distress syndrome (ARDS) model initially ventilated with a protective ventilation. Methods: A prospective and experimental laboratory study where eight Agroceres pigs were instrumented and followed by induction of acute lung injury with sequential pulmonary lavages and injurious ventilation. Afterwards, the animals were ventilated with a tidal volume of 6 mL/kg, followed by a randomized sequence of respiratory rates (30, 60, 60 with pauses of 10 and 30% of the inspiratory time, 90, 120, 150, 60 with alveolar recruitment maneuver and PEEP titration and 5 Hertz of HFOV), until PaCO2 stabilization between 57 63 mmHg for 30 minutes. The Servo-300 ventilator was used for HFPPV and the ventilator SensorMedics 3100B was used for HFOV. Data are shown as median (P25th,P75th). Measurements and Main Results: Animals weight was 34 [29,36] kg. After lung injury, the P/F ratio, pulmonary shunt and static compliance of animals were 92 [63,118] mmHg, 26 [17,31] % and 11 [8,14] mL/cmH2O respectively. The total PEEP used was 14 [10,17] cmH2O throughout the experiment. From the respiratory rates of 35 (while ventilating with 6 mL/kg) to 150 breaths/ minute, the PaCO2 was 81 [78,92] mmHg and 60 [58,63] mmHg (P=0.001), the tidal volume progressively felt from 6.1 [5.9,6.2] to 3.8 [3.7,4.2] mL/kg (P<0.001), the plateau pressure was 29 [26,30] and 27[25,29] cmH2O (P=0.306) respectively. There were no detrimental effects in the hemodynamics and blood oxygenation, while the animals were using a FiO2 = 1. Conclusions: During protective mechanical ventilation, HFPPV delivered by a conventional ventilator in a severe ARDS swine model allows further tidal volume reductions. This strategy also allowed the maintenance of PaCO2 in clinically acceptable levels

Mechanical ventilation can be a life saving treatment. However, due to the inhomogeneous and anisotropic behavior of the lung tissue, ventilation can also lead to overdistensions of lung regions whereas other areas remain even collapsed. A first step is a more comprehensive understanding of the flow mechanics under normal breathing conditions in a healthy lung as well as for a diseased, collapsed lung. This is the aim of this work. Therefore, a realistic model of the upper human airways has been generated at which experimental and numerical investigations could be carried out. Experimentally, the flow was analyzed by means of Particle Image Velocimetry (PIV) measurements which revealed new details about the flow patterns occurring during different ventilation frequencies. Numerical results were in good agreement with the experimental results and could provide new details about the three-dimensional flow structure and emerging secondary flow within the upper airways. The study of reopening of collapsed airways has shown that larger frequencies lead to airway reopening without overdistension of already open parts. Higher frequencies also lead to homogenization of mass flow distribution within the human lung
Künstliche Beatmung ist meist eine lebensrettende Maßnahme. Aufgrund der räumlich anisotropen und inhomogenen Eigenschaften der Lunge kann die Beatmung jedoch auch zu einer Schädigung der Lunge führen. Daraus ergibt sich die Forderung einer „Protektiven Beatmung“. Ein erster Schritt dahingehend ist ein verbessertes Verständnis der Atmung und Beatmung am Beispiel der gesunden sowie kranken, teilweise kollabierten Lunge. Dies ist das Ziel der Arbeit. Hierfür wurde ein realistisches Modell der oberen Atemwege (Tracheobronchialbaum) angefertigt. An diesem Modell können sowohl experimentelle als auch numerische Untersuchungen durchgeführt werden. Experimentell wurde die Strömung mittels Particle Image Velocimetry (PIV) untersucht, wobei neue Details bezüglich der auftretenden Strömungsmuster für unterschiedliche Frequenzen gefunden wurden. Numerische Strömungsberechnungen stimmen gut mit den experimentellen Ergebnissen überein. Dreidimensionale Strömungsstrukturen sowie die Entwicklung von Sekundärwirbeln in der Lunge konnten erklärt werden. Eine Studie am kranken, teilweise kollabierten Lungenmodell zeigte, dass mit steigender Frequenz kollabierte Bereiche wiedereröffnet werden können. Höhere Frequenzen führen weiterhin zu einer Homogenisierung der Massenstromverteilung in der Lunge

Introdução: Um dos principais objetivos na SARA é encontrar a melhor estratégia protetora de ventilação mecânica que minimize o stress pulmonar e otimize as trocas gasosas. Teoricamente, estas duas metas podem ser obtidas simultaneamente, evitando-se a hiperdistensão e colapso cíclico de unidades alveolares instáveis. Numa tentativa de radicalizar a minimização da hiperdistensão e da pressão motriz inspiratória, duas estratégias podem ser propostas: o uso da ventilação de alta freqüência oscilatória (HFOV) e o uso da insuflação intra-traqueal de gás (TGI), esta última associada à hipercapnia permissiva e baixas freqüências respiratórias. Objetivo: identificar qual (quais) entre as três estratégias de ventilação mecânica, HFOV, TGI e ventilação protetora de baixa freqüência (VP: volume corrente ~6 mL/kg), foi (foram) a (s) mais protetora (s) em um modelo de SARA em coelhos, durante seis horas de ventilação mecânica. Material e métodos: Os animais (n = 45) foram submetidos a repetidas lavagens pulmonar até uma PaO2 < 100 mmHg. Imediatamente após a injuria pulmonar, foi obtida uma curva P/V para calculo do trabalho inspiratório e energia dissipada durante insuflação pulmonar. Em seguida, os animais foram randomizados em um dos três grupos: HFOV, VP ou TGI. O PEEP ou PMEAN ideais foram obtidos através de uma curva PEEP/PaO2 (ou PMEAN/PaO2) que foi precedida por uma manobra de recrutamento. Os animais dos grupos VP e TGI foram inicialmente ventilados em PCV com um delta de pressão = 8 cmH2O e freqüência = 60 resp/min. A única diferença inicial entre os dois foi que o grupo TGI possuía um fluxo traqueal continuo = 1 L/min. Os animais do grupo HFOV foram inicialmente ventilados com uma amplitude de pressão = 45 cmH2O e freqüência = 10 Hz. Todos os animais foram ventilados com uma FiO2 = 1.0. Os deltas de pressão (ou pressão motriz) nos grupos VP e TGI foram reajustados para manter uma PaCO2 = 90-110 mmHg, enquanto no HFOV a amplitude de pressão foi reajustada para manter uma PaCO2 = 45-55 mmHg. No final do experimento, outra curva P/V foi obtida. Amostras do LBA e sangue foram coletados antes e após o período de ventilação para determinar os níveis de IL-8. Amostras do pulmão esquerdo foram processadas para análise histológica e para cálculo da relação peso-úmido/ peso-seco. Resultados: Não foi observada diferença na PaO2 entre os grupos. A PaCO2 foi significantemente menor no grupo HFOV (59 ± 3 mmHg) quando comparado aos grupos VP (99 ± 4 mmHg) e TGI (80 ± 3 mmHg). O volume corrente foi significantemente menor nos grupos TGI e HFOV quando comparado ao grupo VP. Logo após a lesão pulmonar, todos os grupos necessitaram de trabalhos similares para a insuflação pulmonar, mas o grupo VP foi o único que não apresentou melhora (diminuição) deste trabalho expiratório, a estratégia VP foi a única que apresentou aumento ao longo das 6 horas (P<0,001). Os grupos TGI e HFOV também apresentaram maiores concentrações de polimorfonucleares no tecido pulmonar (P=0,008) e tendências a favorecer um maior índice superfície/volume (P=0,14), maior gradiente IL-8 (diferença ente IL-8 no LBA e plasma - P=0,08) e menor relação peso-úmido/peso-seco (P=0,17) ao final das 6 horas de ventilação. Discussão: O menor trabalho requerido na insuflação pulmonar depois de 6 horas de ventilação refletiu uma redução nas pressões críticas de abertura e, provavelmente, uma melhora do edema pulmonar e do sistema surfactante nas estratégias HFOV e TGI. O aumento do trabalho expiratório no grupo VP sugere, inclusive, uma deterioração na qualidade do surfactante neste grupo. Nos grupos TGI e HFO, a maior concentração de polimorfonucleares no tecido pulmonar e a tendência a apresentar maior gradiente de IL8 poderiam se interpretados como uma melhor membrana alvéolo-capilar, resultando na menor liberação de mediadores compartimentalizados no interior dos alvéolos. Além de necessitar volumes correntes mais altos, a estratégia VP necessitou de pressões inspiratórias progressivamente mais altas durante as seis horas de protocolo, devido a reajustes freqüentes, necessários à manutenção das trocas gasosas. Conclusão: Uma redução mais radical das pressões motrizes demonstrou efeitos benéficos num modelo de lesão pulmonar aguda experimental, mesmo quando associada a uma estratégia que já prioriza o recrutamento pulmonar ótimo. O TGI mostrou ser uma alternativa viável à HFOV, apresentando algumas vantagens práticas de implementação e em termos de previsibilidade de resposta nas trocas gasosas.
Introduction: One of the major goals in ARDS is to find the best protective mechanical ventilation strategy, which minimizes lung stress and optimizes gas exchange. Theoretically, these two goals can be accomplished by simultaneously avoiding alveolar overdistension and cyclic collapse of unstable alveolar units. Pushing further the rationale of this strategy, two new strategies have been proposed: high frequency oscillatory mechanical ventilation (HFOV) and intra-tracheal gas insufflation (TGI) associated with permissive hypercapnia and conventional frequencies. Objective: To determine which of the three protective modalities of mechanical ventilation, HFOV, low-frequency-protective ventilation (LFV), or LFV associated with tracheal gas insufflation (TGI), was the most protective strategy in an ARDS rabbit model during six hours of mechanical ventilation. Material and methods: The animals (n = 45) were submitted to repeated saline lavage until PaO2 < 100 mmHg. Immediately after lung injury, a P/V curve was obtained to calculate inspiratory/expiratory work and energy dissipated during lung inflation. Thereafter, the animals were randomized into one of three groups: LFV, HFOV or TGI. The optimal PEEP or PMEAN was obtained during a PEEP/PaO2 (or PMEAN/PaO2) curve which was preceded by a recruiting maneuver. The animals of the LFV and TGI groups were initially ventilated in PCV with diving pressure = 8 cmH2O and frequency = 60 b/m. The only initial difference between these two arms was that the TGI group had a continuous tracheal flow = 1 L/min. The animals in the HFOV were initially ventilated with an oscillatory pressure amplitude = 45 cmH2O and frequency = 10 Hz. All animals were ventilated with FiO2 = 1.0. Driving pressure was then adjusted in LFV and TGI groups to maintain a PaCO2 = 90-110 mmHg, while in HFO the pressure amplitude was adjusted to maintain a PaCO2 = 45-55 mmHg. At the end of the experiment, after 6 hours of ventilation, another P/V curve was obtained. BAL and bloods samples were drawn before and after the period of ventilation to determine IL-8 levels. The left lung was processed for histological analysis and for wet weight/dry weight (ww/dw) ratio. Results: We observed no differences in PaO2 among the groups. PaCO2 was significantly lower at HFO (59 ± 3 mmHg) when compared with LFV (99 ± 4 mmHg) and TGI (80 ± 3 mmHg) groups. Tidal volume was significantly lower in TGI and HFO groups when compared with LFV group. Soon after injury, all groups required similar energy for lung inflation (inspiratory work), but the VP group was the only one not presenting any improvement in this parameter after 6 hours (P<0.001). Concerning the expiratory work, the VP strategy was the only one presenting an increase in the expiratory work along the 6 hours (P<0.001). The TGI and HFOV groups showed the highest polymorphonuclear cell concentration in lung tissue (P=0.008) and trends towards a higher surface/volume index (P=0.14), higher IL8 gradient (difference between IL8 in BAL and plasma) and lower ww/dw ratio at the end of 6 hours of ventilation (P=0.17). Discussion: The lower energy for lung inflation after six hours of ventilation reflected the reduction of opening pressures and better surfactant function during ventilation under TGI and HFOV strategies. The increase in expiratory work during the VP strategy further suggests that the surfactant quality deteriorated under this strategy. In the TGI and HFOV groups, the higher concentration of polymorphonuclear cells and the trend towards a higher IL8 gradient between the lung and blood may suggest a better integrity of the alveolar-capillary membrane, leading to less release of compartmentalized mediators within the alveolar space. Besides the higher tidal volumes used during VP, this strategy required inspiratory pressures progressively higher along the hours, due to frequent and necessary adjustments of tidal volumes or pressures according to the gas-exchange requirements. Conclusion: An aggressive reduction of tidal volume and driving pressures was beneficial during protective strategies, even when an optimization of lung recruitment was already in place. The TGI strategy showed to be an attractive alternative to HFOV, presenting some advantages in terms of implementation and predictability of response.

碩士
嘉南藥理大學
醫務管理系
102
Purpose： High frequency oscillatory ventilator (HFOV) reduces lung injury from conventional ventilation and improves oxygenation in patients with acute respiratory distress syndrome (ARDS). The purpose of this study is to investigate factors influencing the effectiveness of HFOV in adult patients. Method： We performed a retrospective study on adult patients, who was treated with HFOV during January 2006 to December 2010, hospitalized in ICU of a medical center in southern Taiwan. The information of gender, age, diagnosis, ICU admission type, APACH II, days of ICU stay, ventilator days were collected. Additionally, the survival of patients, parameters of respiratory system between conventional mechanical ventilation and HFOV were compared using SPSS 17.0 for windows (An IBM Company). In the first part, we used descriptive statistics to analyze background information of patients. Continueously, we used chi-square and the Nonparametric Wilcoxon rank sum test to compare the differences of factors between survivors and non-survivors. The respiratory gas exchange and the parameters of respiratory system before and after using HFOV were analyzed by the nonparametric Wilcoxon signed rank test. The risk factors for mortality were calculated by multiple logistic regression analysis. Result： The data of study were collected from 77 patients. The improvement (P＜0.05) of FiO2, P/F ratio, pH, and PaCO2 in ARDS patients was observed significantly within 72 hours after treating with HFOV. The mean airway pressure (mPaw) was increased significantly, respectively. The significant differences was showed in patients ≧60 years (35% vs. 64.9%,P＜0.05),HFOV hours (129.8±79.7 vs. 99.6±128.1, P＜0.05), mean arterial pressure (91.7±20 vs. 80.1±19.3 mm Hg, P＜0.05) between survivors and non-survivors. Furthermore, the pH level of non-survivors after treating with HFOV was significantly lower than survivors (7.34±0.09 vs. 7.28±0.12, P ＜0.05). however, There is no significant difference in mPaw, oxygen concentration (FiO2), PaCO2, and Oxygenation index between the two groups. Conclusion： HFOV improved gas exchange and increased the P/F ratio and pH level in adult patients. Furthermore, levels of FiO2 and PaCO2 were decreased in ARDS patients, respectively. The efficiency of HFOV peaked at 24 hours and remained constant through 72 hours. Patients with better pulmonary gas exchange before HFOV treated had better prognosis, indicating that early HFOV treated was associated with better outcomes.

During mechanical ventilation, lung volume is determined by the applied transpulmonary pressure. Inappropriate application of this pressure increases the risk of ventilator-induced lung injury and, in the neonate, chronic lung disease. High-frequency oscillatory ventilation (HFOV) has been advocated as a lung protective mode of ventilation. But, even when HFOV is applied with a high lung volume strategy, the reductions in chronic lung disease are modest at best. In general, this is because standard high lung volume strategies do not account for the complex relationship between pressure and lung volume. In part, this is due to difficulties in determining lung volume at the bedside during HFOV.

Mechanical ventilation can be a life saving treatment. However, due to the inhomogeneous and anisotropic behavior of the lung tissue, ventilation can also lead to overdistensions of lung regions whereas other areas remain even collapsed. A first step is a more comprehensive understanding of the flow mechanics under normal breathing conditions in a healthy lung as well as for a diseased, collapsed lung. This is the aim of this work. Therefore, a realistic model of the upper human airways has been generated at which experimental and numerical investigations could be carried out. Experimentally, the flow was analyzed by means of Particle Image Velocimetry (PIV) measurements which revealed new details about the flow patterns occurring during different ventilation frequencies. Numerical results were in good agreement with the experimental results and could provide new details about the three-dimensional flow structure and emerging secondary flow within the upper airways. The study of reopening of collapsed airways has shown that larger frequencies lead to airway reopening without overdistension of already open parts. Higher frequencies also lead to homogenization of mass flow distribution within the human lung.
Künstliche Beatmung ist meist eine lebensrettende Maßnahme. Aufgrund der räumlich anisotropen und inhomogenen Eigenschaften der Lunge kann die Beatmung jedoch auch zu einer Schädigung der Lunge führen. Daraus ergibt sich die Forderung einer „Protektiven Beatmung“. Ein erster Schritt dahingehend ist ein verbessertes Verständnis der Atmung und Beatmung am Beispiel der gesunden sowie kranken, teilweise kollabierten Lunge. Dies ist das Ziel der Arbeit. Hierfür wurde ein realistisches Modell der oberen Atemwege (Tracheobronchialbaum) angefertigt. An diesem Modell können sowohl experimentelle als auch numerische Untersuchungen durchgeführt werden. Experimentell wurde die Strömung mittels Particle Image Velocimetry (PIV) untersucht, wobei neue Details bezüglich der auftretenden Strömungsmuster für unterschiedliche Frequenzen gefunden wurden. Numerische Strömungsberechnungen stimmen gut mit den experimentellen Ergebnissen überein. Dreidimensionale Strömungsstrukturen sowie die Entwicklung von Sekundärwirbeln in der Lunge konnten erklärt werden. Eine Studie am kranken, teilweise kollabierten Lungenmodell zeigte, dass mit steigender Frequenz kollabierte Bereiche wiedereröffnet werden können. Höhere Frequenzen führen weiterhin zu einer Homogenisierung der Massenstromverteilung in der Lunge.