PaulusF, BinnekadeJM, VroomMB, SchultzMJ. Benefits and risks of manual hyperinflation in intubated and mechanically ventilated intensive care unit patients: a systematic review. Crit Care, 2012; 16(4):R145.
2.
BransonRD. Secretion management in the mechanically ventilated patient. Respir Care, 2007; 52(10):1328–1342.
3.
ClementAJ, HubschSK. Chest physiotherapy by the ‘bag squeezing’ method: a guide to technique. Physiotherapy, 1968; 54(10):355–359.
4.
PaulusF, BinnekadeJM, MiddelhoekP, SchuitzMJ, VroomMB. Manual hyperinflation of intubated and mechanically ventilated patients in Dutch intensive care units–a survey into current practice and knowledge. Inten Crit Care Nurs, 2009; 25(4):199–207.
5.
RestrepoRD, BrownJM2nd, HughesJM. on behalf of the American Association for Respiratory Care. AARC Clinical Practice Guidelines. Endotracheal suctioning of mechanically ventilated patients with artificial airways 2010. Respir Care, 2010; 55(6):758–764.
6.
BendixenHH, Hedley-WhyteJ, LaverMB. Impaired oxygenation in surgical patients during general anesthesia with controlled ventilation: a concept of atelectasis. N Engl J Med, 1963; 269:991–996.
7.
NeumannP, BerglundJE, Fernández MondéjarE, MagnussonA, HedenstiernaG. Dynamics of lung collapse and recruitment during prolonged breathing in porcine lung injury. J Appl Physiol, 1998; 85(4):1533–1543.
8.
NeumannP, BerglundJE, MondéjarEF, MagnussonA, HedenstiernaG. Effect of different pressure levels on the dynamics of lung collapse and recruitment in oleic-acid-induced lung injury. Am J Respir Crit Care Med, 1998; 158(5 Pt 1):1636–1643.
9.
MarkstallerK, EberleB, KauczorHU, ScholzA, BinkA, ThelenM, et al. Temporal dynamics of lung aeration determined by dynamic CT in a porcine model of ARDS. Br J Anaesth, 2001; 87(3):459–468.
10.
McCarrenB, ChowCM. Manual hyperinflation: a description of the technique. Aust J Physiother, 1996; 42(3):203–208.
11.
VolpeMS, NavesJM, RibeiroGG, RuasG, TucciMR. Effects of manual hyperinflation, clinical practice versus expert recommendation, on displacement of mucus simulant: a laboratory study. PloS One, 2018; 13(2):e0191787.
12.
StillerK. Physiotherapy in intensive care: an updated systematic review. Chest, 2013; 144(3):825–847.
13.
BerneyS, DenehyL. A comparison of the effects of manual and ventilator hyperinflation on static lung compliance and sputum production in intubated and ventilated intensive care patients. Physiother Res Int, 2002; 7(2):100–108.
14.
AndersonA, AlexandersJ, SinaniC, HayesS, FogartyM. Effects of ventilator vs manual hyperinflation in adults receiving mechanical ventilation: a systematic review of randomised clinical trials. Physiotherapy, 2015; 101(2):103–110.
15.
BenjaminRG, ChapmanGA, KimCS, SacknerMA. Removal of bronchial secretions by two-phase gas-liquid transport. Chest, 1989; 95(3):658–663.
KimCS, RodriguezCR, EldridgeMA, SacknerMA. Criteria for mucus transport in the airways by two-phase gas-liquid flow mechanism. J Appl Physiol, 1986; 60(3):901–907.
19.
FreitagL, LongWM, KimCS, WannerA. Removal of excessive bronchial secretions by asymmetric high-frequency oscillations. J Appl Physiol, 1989; 67(2):614–619.
20.
MariniJJ, GattinoniL. Propagation prevention: a complementary mechanism for “lung protective” ventilation in acute respiratory distress syndrome. Crit Care Med, 2008; 36(12):3252–3258.
21.
Li BassiG, MartiJD, SaucedoL, RigolM, RocaI, CabanasM, et al. Gravity predominates over ventilatory pattern in the prevention of ventilator-associated pneumonia. Crit Care Med, 2014; 42(9):e620–e627.
22.
Li BassiG, MartiJD, ComaruT, Aguilera-XiolE, RigolM, NtoumenopoulosG, et al. Short-term appraisal of the effects and safety of manual versus ventilator hyperinflation in an animal model of severe pneumonia. Respir Care, 2019; 64(7):760–770.
23.
Li BassiG, SaucedoL, MartiJD, RigolM, EsperattiM, LuqueN, et al. Effects of duty cycle and positive end-expiratory pressure on mucus clearance during mechanical ventilation. Crit Care Med, 2012; 40(3):895–902.
24.
MartiJD, Li BassiG, RigolM, SaucedoL, RanzaniOT, EsperattiM, et al. Effects of manual rib cage compressions on expiratory flow and mucus clearance during mechanical ventilation. Crit Care Med, 2013; 41(3):850–856.
25.
PaulusF, VeeloDP, de NijsSB, BeenenLF, BresserP, de MolBA, et al. Manual hyperinflation partly prevents reductions of functional residual capacity in cardiac surgical patients–a randomized controlled trial. Crit Care, 2011; 15(4):R187.
26.
BlattnerC, GuaragnaJC, SaadiE. Oxygenation and static compliance is improved immediately after early manual hyperinflation following myocardial revascularisation: a randomised controlled trial. Aust J Physiother, 2008; 54(3):173–178.
27.
ChoiJS, JonesAY. Effects of manual hyperinflation and suctioning in respiratory mechanics in mechanically ventilated patients with ventilator-associated pneumonia. Aust J Physiother, 2005; 51(1):25–30.
28.
Li BassiG, ComaruT, MartiD, XiolEA, ChiurazziC, TraviersoC, et al. Recruitment manoeuvres dislodge mucus towards the distal airways in an experimental model of severe pneumonia. Br J Anaesth, 2019; 122(2):269–276.
29.
Li BassiG, ZanellaA, CressoniM, StylianouM, KolobowT. Following tracheal intubation, mucus flow is reversed in the semirecumbent position: possible role in the pathogenesis of ventilator-associated pneumonia. Crit Care Med, 2008; 36(2):518–525.
30.
ZanellaA, CressoniM, EppM, HoffmannV, StylianouM, KolobowT. Effects of tracheal orientation on development of ventilator-associated pneumonia: an experimental study. Inten Care Med, 2012; 38(4):677–685.
31.
NtoumenopoulosG, ShannonH, MainE. Do commonly used ventilator settings for mechanically ventilated adults have the potential to embed secretions or promote clearance?. Respir Care, 2011; 56(12):1887–1892.
