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Respiratory physiotherapy in the ICU: Effectiveness and professional certification

Fisioterapia respiratória em UTI: Efetividade e habilitação profissional

Wellington P. S.Yamaguti, Luiz A. Alves, Lucienne T. Q. Cardoso, Carrie C. R. Galvan, Antonio F. Brunetto

Respiratory physiotherapists are increasingly in demand and are ever more frequently seen in intensive care units (ICUs). However, training and qualification are not always sufficient to meet the needs of this demanding environment and to allow these specialists to rise to the level of competence required to be an effective member of a multidisciplinary team. Therefore, the physiotherapist must have a solid education and practical background in order to prescribe, select and apply specific respiratory physiotherapy procedures in resolving complex cases. Otherwise, both the effectiveness of the work and the risks to the patient may increase prohibitively.

As an example of a successful performance, we cite a case of acute lobar atelectasis caused by the accumulation of bronchial secretion. Respiratory physiotherapy is the first course of action in such cases since it involves noninvasive procedures of proven efficiency(1). The 22-year-old patient, having suffered an automobile accident resulting in fracture of the C2 vertebra and a medullary lesion, was interviewed and fitted with a halo device for cranial traction, then admitted to the ICU at the Hospital Universitário Regional do Norte do Paraná (Northern Paraná Regional University Hospital) located in the city of Londrina, in the state of Paraná, Brazil.

After initial clinical improvement, the patient developed acute respiratory insufficiency, requiring invasive mechanical ventilation, which, despite the fact that pressure-controlled ventilation (PCV) was 18 cmH2O, positive end-expiratory pressure (PEEP) was 12 cmH2O and fraction of inspired oxygen was 60% (all relatively high settings), was not sufficient to guarantee adequate oxygenation and alveolar ventilation, as evidenced by the arterial oxygen tension (PaO2) of 61 mmHg and arterial carbon dioxide tension (PaCO2) of 55 mmHg).

Static compliance was assessed at 18 ml/cmH2O. The clinical exam revealed the absence of vesicular murmur, fluid upon percussion and reduced chest expansion, all in the right hemithorax. The chest X-ray showed complete opacification of the right lung and deviation of the mediastinal structures to the right. These findings indicated total atelectasis of the right lung.

The physiotherapy session consisted of the following procedures:
1. Slow thoracic expiratory pressure maneuvers in the right hemithorax(2,3) for 30 minutes.
2. Orotracheal tube aspiration (due to a great quantity of thick mucous secretion).
3. Adjusting the PCV to 25 cmH2O above PEEP, combined with manual restriction of the left hemithorax for 15 minutes.

Due to the cervical traction, the patient remained in the horizontal dorsal decubitus position throughout the treatment. There were no hemodynamic changes during the procedures, and the orotracheal tube was never repositioned.

Thirty minutes after the end of the session, additional tests were conducted. The results of the clinical examination were normal, the chest X-ray showed no abnormalities, static compliance was 30 ml/cmH2O, PaO2 was 126 mmHg, and PaCO2 was 29 mmHg. Mechanical ventilation parameters were adjusted accordingly.

The reversal of atelectasis in intubated patients is achieved through bronchoscopic aspiration(4), manual hyperinflation and periodic aspiration(5) or through respiratory physiotherapy consisting of bronchial hygiene(2,3,6,7) and pulmonary re-expansion techniques(2,6). The choice of techniques to be applied basically depends on initial evaluation of the clinical conditions as well as on patient monitoring, availability of material resources and the personal preferences of the physiotherapist.

In this case, the cervical traction device precluded placing the patient in any position other than the dorsal decubitus. Therefore, it was not possible to use the left lateral decubitus position, which is the most favorable for right-side drainage of bronchial secretions and pulmonary re-expansion(6,8). The application of thoracic expiratory pressure maneuvers directly to the costal grid(9), a manual technique based on increasing expiratory flow in order to carry secretions towards the proximal airways (from where they can be aspirated), was therefore indicated.

After the bronchial hygiene therapy had been performed, the PCV was increased (from the previous setting of 18 cmH2O above PEEP) to 25 cmH2O above PEEP, with the objective of recruiting collapsed alveolar units and promoting pulmonary re-expansion. This procedure can be considered a mechanical hyperinflation maneuver, having an advantage over the manual procedure due to greater control of the peak inspiratory pressure (PIP) applied (PCV at 25 cmH2O + PEEP at 12 cmH2O = PIP at 37 cmH2O), an important factor in the prevention of barotrauma(10). The manual containment of the left hemithorax by the physiotherapist has the objective of driving the flow volume to the right hemithorax, promoting greater recruitment of collapsed areas. Such a maneuver would have been unnecessary if the patient could have been placed in the left lateral decubitus position.

In the case cited, the complexity of the job of the physiotherapist is explicit in terms of the need for effectiveness in carrying out procedures and for controlling patient risk. Therefore, appropriate certification of these professionals, perhaps through physiotherapy residencies, is imperative. Only physiotherapists who have had adequate training and experience can be fully integrated into multidisciplinary teams acting in ICUs.

REFERENCES

1. Van der Schans CP, Postma DS, Koëter GH, Rubin BK. Physiotherapy and bronchial mucus transport. Eur Respir J. 1999;13:1477-86
2. Costa D. Manobras manuais na fisioterapia respiratória. Fisioterapia em Movimento. 1991; 4:11-25.
3. Bach JR, Smith WH, Michaels J, Saporito L, Alba AS, Dayal R, Pan J. Airway secretion clearence by mechanical exsufflation for post-poliomyelitis ventilator-assisted individuals. Arch Phys Med Rehabil. 1993;74:170-7.
4. Marini JJ, Pierson DJ, Hudson LD. Acute lobar atelectasis: a prospective comparasion of the fibreoptic broncoscopy and respiratory therapy. Am Rev Respir Dis. 1979;119: 971-8.
5. Cook N. Respiratory care in spinal cord injury with associated traumatic brain injury: bridging the gap in critical care nursing interventions. Int Crit Care Nurs. 2003;19:143-53.
6. Ciesla ND. Chest physical therapy for patients in the intensive care unit. Phys Ther. 1996;76:609-25.
7. Pryor JA. Physiotherapy for airway clearance in adults. Eur Respir J. 1999;14:1418-24.
8. Ribeiro EC. Considerações sobre o posicionamento durante a fisioterapia respiratória. Rev Bras Fisiot. 1996;1:61-5.
9. Kim C, Iglesias A, Rodriguez C. Mucus transport by two-phase gas-liquid flow mechanism during periodic flow. Am Rev Respir Dis. 1984;129:A373.
10. Haake R, Schlictig R, Ulstad D, Henschen R. Barotrauma: pathophysioloy, risk fators, and prevention. Chest. 1987;91:608-13.


Respiratory Physiotherapy Research Laboratory
Hospital Universitário da Universidade Estadual de Londrina
E-mail: brunetto@uel.br






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