Clinical Trials Logo

Clinical Trial Summary

Acute exacerbation of chronic obstructive pulmonary disease (COPD) is defined acute worsening of respiratory symptoms requiring additional therapy. COPD exacerbations affects the health status and quality of life of affected patients. The inpatient mortality during exacerbation is 3 to 4% while, intensive care unit (ICU) mortality approaches 43 to 46%. Each episode of exacerbation increases the risk of mortality subsequently(1) Non-invasive ventilation (NIV) therapy has established role in mild to moderate exacerbations of COPD. But the use of NIV therapy outside of acute exacerbation is uncertain(2) NIV use has been shown to prevent endotracheal intubation and improved hospital and ICU survival. NIV decreases the work of breathing by unloading the respiratory muscles through assisting the inspiratory phases and counterbalancing the intrinistic positive end expiratory positive pressure (ipeep)(3). NIV is delivered through face mask, although newer interfaces like helmet available(3). Tradionally pressure targeted mode is used in NIV therapy and is often given intermittently rather than continuously(4). NIV therapy via face mask was first used by Meduri et. Al in acute respiratory failure patients. Subsequent multiple randomized control trials established the role of NIV therapy in better gas exchange, reducing PCO2, reducing endotracheal intubation thereby reducing mortality, length of stay in hospital(3). NIV-PSV (pressure support ventilation) consists of 2 pressures. IPAP (inspiratory positive airway pressure) and EPAP (expiratory positive airway pressure) or PEEP. Pressure support is usually the pressure added above PEEP. Pressure support is usually started with 8-10 cm H2O to obtain a tidal volume of 6-8ml/kg ideal body weight. EPAP/PEEP is adjusted to counterbalance the iPEEP. It is usually kept at 4-6cm H2O. Fio2 is kept to maintain saturation of 88-92%. Inspiratory trigger is usually set at 1 L/min. Expiratory trigger kept at 50%. Back up rate should always be kept usually lower than the patient respiratory rate 10-12 breaths/min(5). Adaptive support ventilation (ASV) is a new method of closed loop ventilation which can switch back between pressure support and pressure control modes of ventilation. Based on the ideal body weight and % of minute volume ventilation given, the ASV mode choses the best tidal volume and respiratory rate according to the patient lung mechanics by calculating expiratory time constant (RCe) through expiratory flow volume curve(6). Since closed loop system, being a completely automated system, prevent frequent adjustment by clinician and thereby increasing the time and capacity of medical staff. The first application of such closed loop system in mechanical ventilation was done by saxton in1953 in iron lung for regulation of etCO2(7). Studies published on ASV as non-invasive mode of ventilation is limited. In a feasibility study, it has been shown that ASV can be used in non-invasive mode of ventilation with similar results to PSV in COPD patients(8).


Clinical Trial Description

Acute exacerbation of chronic obstructive pulmonary disease are periods of acute worsening during the course of illness which increase hospital admission and mortality. Intensive care unit admission and mortality are higher among elderly and those with co-morbidities(9). Non-invasive methods of ventilation can be used in mild to moderate exacerbation of COPD. They prevent most of the complications of invasive mechanical ventilation and has also reduces mortality in acute exacerbations of COPD. In mild to moderate COPD exacerbations(pH-7.25 to 7.35), non-invasive ventilation (NIV) failure rate is found to be 15% to 20%. In severe COPD exacerbations, NIV failure rate approaches upto 52% to 62%(9). Adaptive support ventilation (ASV) and pressure support ventilation (PSV) are among the non-invasive modes of ventilation used in COPD exacerbations. Adaptive support ventilation: Adaptive support ventilation is a closed loop ventilation in which it provides both pressure support and pressure controlled ventilation as per the patient needs(10). The mode was first described by Hewlett in 1977 in form of mandatory minute ventilation with adaptive pressure control(11). Later Dr. fleur T Tehrani invented this mode, which was later introduced in Galileo ventilator(11). This mode supports patient with pressure support when patient has spontaneous breath and when target ventilation is not reached it delivers pressure control breath to achieve adequate ventilation. In this mode, minute volume is controlled via Vt/RR combination based on respiratory mechanics of the patient to keep the work of breathing at minimum(10). This mode calculates the tidal volume and respiratory rate to be delivered by otis equation in its algorithm after %minute volume being set by the clinician to ensure effective ventilation at the alveolar level. The inputs provided by the clinician in this mode is %minute volume based on ideal body weight, ETS, flow trigger, maximum pressure limit(12). The mode after being initiated will deliver a series of 5 pressure limited breaths and deliver a inspiratory pressure15 cm h2o above the baseline pressure during which it calculates dynamic compliance, RCe, tidal volume and respiratory rate. These measurements are used to determine the initial targets of breath rate and tidal volume(12). After which based on respiratory rate and effort of the patient, inspiratory pressure, mandatory breath are adjusted automatically to meet the set %minute volume. ASV mode can be used as initiation, maintenance and weaning phases of mechanical ventilation and it provides full, partial or minimal ventilator support during any of these phases(12). The number of manual ventilatory adjustments are less compared to conventional mode of ventilation in ASV(13). Some randomized controlled trials performed in Non-COPD suggest shorter weaning time with ASV mode of ventilation. Shorter weaning is attributed to automated inspiratory pressure change according to patient efforts, thereby reducing ventilator patient dysynchrony and frequency of manual manipulation. In a randomized control study done by c. kirakli et. Al found out that in COPD patients ASV mode of ventilation(24 hours) has shorter weaning duration compared to pressure support mode of ventilation(72 hours) (p-value 0.041). But, this study has not found any difference in the duration of mechanical ventilation, length of stay in ICU, weaning failures when ASV and PSV mode were compared(p-value>0.05)(10) A randomized controlled trial conducted among 80 patients by Bialais et. al comparing safety, efficacy and workload of intellivent- ASV and conventional mode of ventilation (pressure assist mode and pressure support mode) found out that tidal volume delivery and spo2 were most of the time in the optimal range (6-10ml/kg IBW, spo2-92 to 96% for normal lung/ ARDS and 95-99% for brain injury) for intellivent-ASV compared to conventional mode of ventilation(p-value-0.001 and 0.005). However it was found that Pmax (maximum inspiratory pressure measured) was higher (24±5 versus 22±6) with intellivent-ASV mode than conventional ventilation(p-value-0.042). There was no significant difference between intellivent-ASV and conventional mode of ventilation in terms of time spent in optimal range of parameters like respiratory rate, PETCO2, PEEP, minute ventilation, FIO2 , RCexp. There was also no difference in length of mechanical ventilation, length of ICU stay, length of hospital stay, ICU mortality, hospital mortality and total mortality. There was comparative less need for ventilator adjustment with intellivent-ASV mode compared with conventional mode of ventilation(14). A randomized control trial by kirakli et. Al among 229 patients found out that median mechanical ventilation duration until weaning(67{43-94} vs 92{61-165}) p-value-0.003, weaning duration(2{2-2} vs 2{2-80}hours p value-0.001) and total mechanical ventilation duration (4{2-6} days vs 4 {3-9} days, p value-0.016) were shorter in ASV group compared to pressure assist/control ventilation. Also the number of patients succeeding first attempt of extubation was higher in ASV group (p value-0.001). Weaning success and mortality were comparable between the two groups(15). NIV-PSV: Mechanical ventilation in its first form was used at the end of 1930s called tank ventilator. Later in 1950s during the polio epidemics, modern mechanical ventilators began to emerge. Intermittent positive pressure application via anaesthesia mask in treatment of acute respiratory illness was studied in motley and colleagues at Bellevue hospital in 1940s. The first application of NIV as CPAP via nasal mask to obstructive sleep apnea patients was done by Sullivan et. Al in 1981. Successful application of NIV via full face mask for respiratory failure in COPD patients, heart failure patients in 1989 avoided intubation. The use of NIV has increased with the introduction of ventilators with effective compensation for air leaks. NIV are most commonly used in obstructive sleep apnea, COPD and cardiac failure patients and to some extent in failed extubation. Although invasive mechanical ventilation has kept the NIV at second place, still it is used in above clinical settings(16). In a study conducted by Hilbert et. Al, NIV-PSV was compared with standard medical treatment in COPD patients. It was found out that the days of ventilator assistance and length of ICU stay has significantly lower with NIV-PSV treated group (7±4 days vs 10±15 days, p<0.01) & (9±4 days vs 21±12 days, p <0.01) respectively. Also NIV support prevented tracheal intubation in acute exacerbation of COPD patients significantly (26% vs 71%) compared to standard medical therapy(17). Randomized control study conducted by laurent et.al suggested that non-invasive ventilation compared to standard medical treatment for COPD exacerbation could reduce the intubation rates, length of stay in hospital(18). Another study by plant et. Al replicated the same results that early NIV therapy would reduce the number of intubation needed in mild to moderate exacerbation of COPD patients and improvement in paco2 and respiratory rate. This study suggested that NIV therapy can be effectively administered in general respiratory wards also(19). NIV therapy was used in hypoxemic respiratory failure in post-abdominal surgery patients compared with oxygen therapy alone by jaber et. Al. NIV therapy has significantly reduced tracheal reintubation rates within 7 days following surgery (33.1% vs 45.5%, p value - 0.03) and also it provided more invasive ventilation free days compared with standard oxygen therapy(25.4 vs 23.2 days). Gas exchange was found to be similar with NIV and standard oxygen therapy in hypoxemic respiratory failure in this study. Also, the NIV group had fewer pulmonary infections compared with oxygen therapy group(20). A randomized study by Nava et. Al conducted to study the effectiveness of NIV to prevent reintubation suggested that early institution of NIV after extubation especially in high risk patients ie) COPD, Cardiac failure, hypercapneic patients may prevent reintubation rates(4/48 vs 12/49, p-value-0.027). The delayed delivery of NIV after extubation can cause increase in mortality. So , timely delivery of NIV support can reduce mortality upto 60%. In this study NIV support was given atleast 8 hours/day after extubation(21). Patient-ventilator asynchrony is well known in patients who are mechanically ventilated. Although there are no studies that suggest direct patient related outcome due to asynchrony, it is well known patient-ventilator asynchrony prolong the duration of mechanical ventilation(22). Although correlation with oesophageal pressure is the standard way of detecting the patient-ventilator asynchrony, a trained eye can detect most of the asynchronies using pressure-time or flow-time waveform analysis(23).Multiple studies has suggested better patient-ventilator interactions with adaptive support mode of ventilation requiring less manipulations from the clinician and also facilitating early liberation from mechanical ventilation compared to other modes of ventilation(24-26). ;


Study Design


Related Conditions & MeSH terms


NCT number NCT06160687
Study type Interventional
Source Postgraduate Institute of Medical Education and Research
Contact
Status Recruiting
Phase N/A
Start date December 1, 2023
Completion date January 31, 2025

See also
  Status Clinical Trial Phase
Active, not recruiting NCT06000696 - Healthy at Home Pilot
Recruiting NCT03250000 - Changes in Microcirculation and Functional Status During Exacerbation of COPD N/A
Recruiting NCT04142827 - The Effect of Long Term Therapy With High Flow Humidification Compared to Usual Care in Patients With Bronchiectasis (BX) N/A
Recruiting NCT05865184 - Evaluation of Home-based Sensor System to Detect Health Decompensation in Elderly Patients With History of CHF or COPD
Completed NCT01892566 - Using Mobile Health to Respond Early to Acute Exacerbations of COPD in HIV N/A
Completed NCT04119856 - Outgoing Lung Team - a Cross-sectorial Intervention in Patients With COPD N/A
Recruiting NCT06118632 - Physiological and Environmental Data in a Remote Setting to Predict Exacerbation Events in Patients With Chronic Obstructive Pulmonary Disease
Recruiting NCT04860375 - Multidisciplinary Management of Severe COPD N/A
Completed NCT04170361 - The Effect of Incentive Spirometry Added to Routine Physiotherapy Program on Hemodynamic Responses and Hospital Stay in Patients With COPD Exacerbation N/A
Not yet recruiting NCT03696563 - FreeO2 PreHospital - Automated Oxygen Titration vs Manual Titration According to the BLS-PCS N/A
Not yet recruiting NCT03296215 - Pattern of Admitted Cases in Respiratory Intensive Care Unit at Assiut University Hospitals N/A
Completed NCT02912689 - NIV - NAVA vs NIV - PS for COPD Exacerbation N/A
Completed NCT03003702 - Domiciliary Monitoring to Predict Exacerbations of COPD N/A
Recruiting NCT02264483 - Low-dose CT for Diagnosis of Pneumonia in COPD Exacerbations and Comparison of the Inflammatory Profile. N/A
Completed NCT01443845 - Roflumilast in Chronic Obstructive Pulmonary Disease (COPD) Patients Treated With Fixed Dose Combinations of Long-acting β2-agonist (LABA) and Inhaled Corticosteroid (ICS) Phase 4
Recruiting NCT02065921 - Swiss Chronic Obstructive Pulmonary Disease (COPD) Management Cohort
Completed NCT04880486 - Weight Training With VR in Out-Patients With Acute Exacerbation of Chronic Obstructive Pulmonary Disease N/A
Recruiting NCT03286127 - Palliative Outcome Evaluation Muenster I
Recruiting NCT04638920 - Molecular Breath Print of COPD Patients With Exacerbations Despite Triple Inhalational Therapy
Not yet recruiting NCT05897125 - Telehealth Education Leveraging Electronic Transitions Of Care for COPD Patients N/A