Traditional chest drainage systems can present problems. A trust found that digital drainage systems improved treatment times and patient mobility
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In this article…
- Problems with traditional chest drainage systems
- How a trial of digital thoracic drains was set up
- Benefits of digital drains for patients and staff
Debbie Danitsch is consultant nurse cardiothoracic, University Hospital of North Staffordshire.
Danitsch D (2012) Benefits of digital thoracic drainage systems. Nursing Times; 108: 11, 16-17.
A number of risks and complications are associated with traditional chest drainage systems. A trust decided to trial digital drainage systems, and found the new systems improved treatment time and patient mobility.
Keywords: Chest drains/Suction/Digital thoracic drains
- This article has been double-blind peer reviewed
- Figures and tables can be seen in the attached print-friendly PDF file of the complete article
5 key points
- There are complications and risks associated with traditional chest drainage systems
- Digital drainage systems offer more accurate monitoring and a more scientific rationale for removal
- Patient mobility is also improved due to the light weight of the drains
- Using digital drainage systems after thoracic surgery is becoming accepted as a safe method for draining air and pleural fluid
- Other patient groups may also benefit from digital drains
Chest drains are placed in the pleural space to evacuate an abnormal collection of air, fluid, pus or solids that may have collected as a result of injury, disease or surgical procedures (Allibone, 2005). They help to restore and maintain the negative pressure between the visceral and parietal pleural membranes, allowing full expansion of the lung.
Air leaks are one of the most common complications after pulmonary resection and are the most frequent cause of prolonged hospital stay, increased costs and patient dissatisfaction (Cerfolio and Bryant, 2009).
Traditionally, chest drains have been attached to an underwater seal drainage system, which acts as a one-way valve allowing fluid and air to leave the pleural space during expiration and coughing but preventing it from being sucked back in during inspiration (Allibone, 2005). However, there are complications and risks associated with this type of drainage system.
If patients have an effective cough combined with a functional underwater seal they may be able to reinflate the lung. However, if the lung does not reinflate or a persistent air leak prevents reinflation, high-volume, low-pressure thoracic suction in the range of 3-5kPa may be used (Havelock et al, 2010; Laws et al, 2003).
The use of suction after thoracic surgery is controversial; some surgeons always use it while others feel it is hazardous. For example, a medical device alert was issued after a patient with a chest drain under active wall suction sustained a tension pneumothorax due to the incorrect use of suction systems with no reservoir in situ (MHRA, 2010).
Another issue with wall suction is the reliability of the pressure. In my clinical experience I have seen the dials fluctuate without being altered by the team. This is supported by Rathinam et al (2011), who noted the variability in flow in wall suction, which can depend on the length of tubing used between the wall suction and the bottle, and between the bottle and
Furthermore, Varela et al (2009) found a high level of disagreement among doctors on the indication to remove chest drains after lung resection. Using digital devices led to improved levels of agreement between medical staff of when to remove the drain.
The immobility that traditional chest drains cause for patients is a considerable source of morbidity (Joshi, 2009). When attached to wall suction many patients have to toilet and wash at the bedside. In fact, there is very limited evidence of the benefits of suction per se but despite this it continues to be used (Deng et al, 2010).
In trying to overcome some of the problems associated with an underwater seal drain and suction apparatus, we explored the concept and use of digital drains. Cerfolio and Bryant (2009) demonstrated that patient management is optimised when air leaks are scientifically evaluated.
Digital drainage systems
One study had identified the accuracy of Medela’s Thopaz digital drainage system (Cerfolio and Bryant, 2009).
As we had no previous experience in using digital drains we undertook a trial of a digital drainage system in 2010. The drains are lightweight, compact and easy for patients to carry after thoracic surgery. Rathinam et al (2011) found that both patients and staff supported this view. The drains also appeared simple to use, which made it easier to introduce them into the ward and theatre. They allow scientific monitoring of patients’ progress and a more scientific rationale for managing and removing the drain.
Patient mobility is also improved due to the light weight of the drains and ability to offer portable suction, which may reduce complications associated with decreased mobility, and improve privacy and dignity.
Trial of digital drains
The trial was undertaken on patients operated on by one thoracic surgeon. The machines were interrogated and provided information on the duration the drain was in situ and the flow rate.
The flow rate enables the size of an air leak to be quantified as a number in ml/breath. This data was collected on 40 patients who had undergone various thoracic procedures, such as lobectomies and wedge resections. The drains were simple to use and posed no problems for nurses to develop competence. Since the systems were introduced there have been no clinical incidents related to them.
On examining the data it became apparent that drains were often left in situ for many hours longer than they needed to be, as patients’ lungs were fully inflated with no air leak present (Fig 1). The drains were left in situ for the “total treatment time”, but the reduction in flow is indicative that the lung was inflated and the drain could have been taken out after the “improved treatment time” period.
Although the data showed improvement in treatment times it did not offer a comparison between traditional and digital drains. However, the number of thoracic cases in our trust has tripled over the last year, with a reduction in length of stays since digital drains were introduced and changes in practice such as same-day admissions.
This concurs with other evidence showing that postoperative air leaks are a major source of bed occupancy after thoracic surgery (Cerfolio and Bryant, 2009). This evidence and other research (Cerfolio and Bryant, 2008) gave us enough information to develop a business case to purchase eight of the digital drainage systems.
Having used the drains for over 12 months we have now developed a nurse-led protocol, and are in the process of testing whether its use affects the length of time the drain is in situ and the overall length of patient stay.
Other potential uses for digital drains
The use of digital drainage systems after thoracic surgery is becoming accepted as a safe method for draining air and pleural fluid (Mier et al, 2010; Papagiannopoulos et al, 2009; Cerfolio and Bryant, 2008) and has been successfully adopted in our unit.
In addition, patients who, despite treatment, cannot reinflate their lung may be discharged home with them, which is being practised in one regional hospital. It may also allow patients to be successfully transferred to a ward level (progressive care) bed with a digital drain, freeing up a high dependency bed.
The increased mobility offered by digital drains may mean that medical patients admitted with a pneumothorax and needing suction to the drain may have reduced length of stay and fewer complications associated with immobility.
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Allibone L (2005) Principles for inserting and managing chest drains. Nursing Times; 101: 42, 45. http://tinyurl.com/NT-chest-drain
Cerfolio RJ, Bryant AS (2009) The quantification of postoperative air leaks. Multimedia Manual of Cardiothoracic Surgery; doi: 10.1510/mmcts.2007.003129.
Cerfolio RJ, Bryant AS (2008) The benefits of continuous and digital air leak assessment after elective pulmonary resection: a prospective study. Annals of Thoracic Surgery; 86: 2, 396-401.
Deng B et al (2010) Suction or non-suction to the underwater seal drains following pulmonary operation: meta-analysis of randomised controlled trials. European Journal of Cardiothoracic Surgery; 38: 210-215.
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Joshi JM (2009) Ambulatory chest drainage. Indian Journal of Chest Diseases and Allied Sciences; 51: 4, 225-231.
Mier JM et al (2010) The benefits of digital air leak assessment after pulmonary resection: prospective and comparative study. Cirugía Espaňola; 87: 6, 385-389.
Laws D et al (2003) BTS guidelines for the insertion of a chest drain. Thorax; 58: ii53-ii59.
Medicines and Healthcare products Regulatory Agency (2010) Medical Device Alert: All Chest Drains When Used with High-flow, Low-vacuum Suction Systems (Wall Mounted) (MDA/2010/040). London: MHRA. http://tinyurl.com/MHRA-suction
Papagiannopoulos K et al (2009) The Use of Thopaz in the Management of Air Leaks. A Transition from Analogue to Standardised Digital Scoring. Experience of first 100 cases from a single institution. Presented at European Society of Thoracic Surgeons conference.
Rathinam S et al (2011) Thopaz portable suction systems in thoracic surgery: an end user assessment and feedback in a tertiary unit. Journal of Cardiothoracic Surgery; 21: 6, 59.
Varela G et al (2009) Post-operative chest tube management: measuring air leaks using an electronic device decreases variability in clinical practice. European Journal of Cardiothoracic Surgery; 35: 1, 28-31.