#38802: Respiratory Care: Artificial Airways, Mechanical Ventilation, and Chest Tubes

Endotracheal intubation (by nasal or oral routes) is one of the most widely used methods to institute and maintain an open airway. Placement of an endotracheal tube requires the use of a laryngoscope to visualize the area and facilitate passage of the tube into the trachea. Prior to intubation, whether oral or nasal, the airway should be assessed following the mneumonic LEMON to ensure safe intubation [10]:

Endotracheal tubes are single-use and constructed of polyvinylchloride (PVC) [11]. They range in size from 2.5 mm to 8 mm in diameter. The tubes may also be uncuffed or cuffed, the latter of which includes an inflatable balloon to help prevent gastric contents from entering the trachea and to ensure a specific positive pressure is maintained. Uncuffed tubes are generally an option for pediatric patients; most adult patients will receive a cuffed tube. A tube that is too large can damage the airway structure and mucosal lining; a tube that is too small will not allow adequate ventilation. The tube should be inserted gently to avoid structural damage. Usually, adult men will require size 8 and adult women size 7, but this can vary depending on the size of the individual and the patient's specific anatomy. The sizing for pediatric patients is (age/4) +4 for uncuffed tubes; if a cuffed tube is used, size down one-half size [12,13]. The oral route is most often employed when emergency intubation is required because of the relative ease of insertion.

Generally, with orotracheal intubations, depending on the situation, medications to block neuromuscular actions and provide adequate sedation are used. This also allows for the prevention of vomiting and aspiration of gastric contents [14,15]. In addition, the airway should be cleared of any debris (e.g., dentures), if applicable.

The proper procedure for orotracheal intubation consists first of preoxygenating the patient (if possible) and administering medications, if indicated, often simultaneously with preoxygenation. The patient is then placed in the "sniffing" position, with the patient in the supine position, head elevated, and neck extended. Intubation of the trachea is then achieved with direct visualization using a laryngoscope. The balloon of the tube is inflated after it is properly placed 3-4 cm past the vocal cords, then the tube is properly secured.

Nasotracheal intubations are also used in a variety of settings. It involves a nasal trumpet along with the endotracheal tube. The nasal trumpet is well lubricated and then inserted through the nare into the nasopharynx. The trumpet dilates the nasal cavity prior to inserting the endotracheal tube. After the tube is passed successfully through the nasopharynx, a laryngoscope is used to visualize the vocal cords for successful passage into the trachea. The cuff on the tube is then inflated to the proper measurement and the tube secured [15,16,17]. Preoxygenation of the patient is ideal but not always available in emergent situations [17]. Proper placement is verified by end-tidal carbon dioxide measurements, capnography, chest x-ray, ultrasound, and clinical assessment [14,15,17].

Proper sizing of nasal trumpets is important to avoid trauma or poor airway management. The size of the nasal trumpet is chosen particularly based on length rather than diameter, as the correct length ensures the tip sits just superior to the epiglottis. A measurement is taken from the lateral aspect of the nares to the tragus of the ear on the same side to determine the correct length [18]. Nasal trumpets are typically made of soft rubber or plastic.

While nasotracheal intubation does have advantages, such less sedation required, there are many disadvantages and potential complications as well, including nasal damage, sinusitis sepsis, and local abscess. Nasopharyngeal airways also pose increased difficulty with pulmonary toileting and have greater airway resistance due to the use of narrower tubes [19,20]. Thus, the use of long-term nasopharyngeal airways is limited. Nasotracheal intubation may be indicated in the following situations [21]:

Absolute contraindications for nasotracheal intubation include [21]:

Relative contraindications include:

Anesthesia uses nasotracheal intubations frequently, dependent on the situation or type of procedure being performed. As the endotracheal tube is introduced into the trachea through the nasal cavity, the tube is easier to stabilize through the nasal pathways due to its small diameter compared with the oral cavity. Nasotracheal intubation is the preferred method for anesthesiologists and surgeons who perform surgeries in the head and neck region, especially oropharyngeal, dental, and maxillofacial surgeries, as this method helps to improve the field of view and access for surgery [22].

Other methods of establishing an artificial airway include tracheotomy and cricothyroidotomy. The tracheotomy was one of the earliest surgical procedures recorded, dating back to 3600 B.C.E. in Ancient Egypt. Today, tracheotomies can be temporary or permanent. The Eastern Association of Surgical Trauma (EAST) recommends early tracheostomy (within three to seven days after intubation) for patients who have severe closed-head injuries or for patients who require prolonged ventilatory support. In non-trauma-type patients with failed ventilator weaning for a variety of different reasons, tracheostomy at post-intubation between days five and seven has been recommended by various professional organizations [23].

Tracheotomy tubes are placed during these procedures. These short, curved tubes have a flange that assists in stabilization of the device on the neck. A variety of tubes are available, including metal or disposable silicone types in several sizes. Most tubes have an inner cannula to facilitate cleansing and are packaged with an obturator, which is used to minimize trauma when the tube is inserted [5,6].

The terms "tracheotomy tube," "tracheostomy tube," and "laryngectomy tube" are often used interchangeably. Actually, a laryngectomy tube is shorter and consists of an obturator, inner cannula, and outer cannula. These tubes are usually placed following a total laryngectomy to provide a route for removal of secretions and to maintain a patent airway [6].

Although there are other types of mechanical ventilators, such as negative pressure and CPAP devices, what is commonly referred to as a ventilator is a conventional positive pressure machine. These work by creating higher than atmospheric pressure to push air into the patient's lungs. Positive-pressure mechanical ventilators are pressure-cycled, volume-cycled, or a combination of both. Other, less common types include airway pressure release ventilation (APRV) and bilevel ventilation; discussion of these types is outside of the scope of this course [3,9,26].

With pressure-cycled or pressure-limited ventilation, air is delivered to the lungs until a predetermined pressure is reached, then inspiration is terminated. Pressure support cycles are typically used when weaning a patient from mechanical ventilation. The disadvantage of this is that the tidal volume delivered to the patient can vary with each inspiration, depending on his or her airway [3,9]. The main advantage is the lungs are protected from overinflation due to excessive pressure.

In volume-cycled or volume-limited ventilation, a set amount of air is delivered for each inspiration. The advantage of this form of ventilation is that the tidal volume remains consistent and the pressure necessary to deliver the volume varies, dependent on the patient's lung compliance. Volume-cycled is the most frequently used type of ventilation for adult patients [9].

There are four common ventilation patterns: assist-control (A/C), intermittent mandatory ventilation (IMV), synchronized intermittent mandatory ventilation (SIMV), and positive end-expiratory pressure (PEEP). In assist-control mode, the inspiratory phase is initiated by the patient. However, modern ventilators have a built-in safety feature to ensure that the machine will deliver the volume at the ordered rate if the patient becomes apneic. In controlled ventilation, the machine has complete control of the patient's rate and depth of ventilation [2,3].

IMV delivers a preset tidal volume at a specific rate while also providing a continuous flow of air for spontaneous breaths. IMV was originally introduced for the purpose of gradually weaning individuals from ventilators, but the use of this type of ventilation has expanded, and it has become popular for patients who require mechanical ventilation but are able to initiate some inspiratory effort on their own, such as patients with chronic obstructive pulmonary disease. IMV cannot be used for individuals who are apneic (e.g., those who have suffered damage to the brain stem). An advantage of IMV ventilation is that it allows the patient to use respiratory muscles, which prevents atrophy [2,3,5,6].

With SIMV, air is delivered by the ventilator in synchronization with the patient's own ventilation efforts. If the SIMV is set at a rate of 10, the patient is assisted 10 times per minute [6].

PEEP prevents the collapse of the airways and alveoli at the end of expiration, facilitating the diffusion of more oxygen from the alveoli into the pulmonary capillaries. This allows for a reduction in inspired oxygen concentrations, because oxygen can diffuse during both inspiration and expiration. The setting for PEEP is usually in the range of 1–15 cm. However, levels greater than 40 cm have been used when treating patients with severe hypoxemia, as in those with acute respiratory distress syndrome [2,6].

Physiologic changes occur with the administration of PEEP. PEEP causes an increase in intrathoracic pressure, which decreases the venous return of blood to the heart. The baroreceptors in the thoracic aorta interpret the decreased venous return as hypovolemia and stimulate an increase in production of antidiuretic hormone (ADH). Increased ADH can lead to the development of hypervolemia, which results in decreased cardiac output. Another potential problem encountered is the development of a pneumothorax [2,6].

Nurses should take steps to ensure the comfort and safety of mechanically ventilated patients. Accidental disconnection of the patient from the ventilator should be prevented. A warning should be placed on all ventilators and on the nursing care plan reminding healthcare personnel to leave the ventilator alarm on at all times, even during suctioning. The sound of the alarm is a minor nuisance compared to the damage that may occur if someone fails to turn the alarm back on (in some cases due to alarm fatigue) [2,5].

A bag-valve mask (e.g., Ambu bag) should be kept at the patient's bedside to be used in the event of a power failure or ventilator malfunction. If the ventilator is not working properly, do not waste time trying to identify the mechanical difficulty. Instead, use the bag-valve mask to ventilate the patient while another staff member calls the respiratory maintenance technician [5].

Patients who are mechanically ventilated often require monitoring of central venous pressure or pulmonary capillary wedge pressures. The positive pressure exerted by the ventilator will alter these readings. It is important that they always be taken either with the patient connected to or disconnected from the ventilator in order to maintain consistency [2,5,26].

As a rule, respiratory therapists are responsible for checking the function of the ventilator at regular intervals. However, nurses should also be familiar with the machine and how it functions [6,26]. The pressure indicator shows the amount of force required to ventilate the patient's lungs. If the amount of pressure required increases or decreases significantly, assess the situation to determine the cause, if possible. If any alarm sounds on the ventilator, it is crucial to respond immediately. If the reason for the alarm cannot be readily ascertained and rectified, the patient should be disconnected from the ventilator and ventilated manually with a bag-valve mask until the ventilator can be replaced or fixed. Because the alarms can be frightening to patients and any others in the room, reassure them that the patient can be adequately oxygenated [6].

The settings on the ventilator should be checked hourly. This includes making sure the tidal volume, respiratory rate, fraction of inspired oxygen (FiO₂), and other parameters are set as ordered. Also, the ventilator tubing should be checked for water condensation; if any is found, the tubing should be disconnected and the water emptied. This will prevent impairment of ventilation or accidental aspiration of water into the trachea [2,6,13,26].

In addition to checking the ventilator, carefully assess the patient for overt clinical signs of hypoxia, hypocapnia, or hypercapnia. Arterial blood gas values should be obtained at regular intervals. Monitoring these values is particularly important when ventilator settlings are changed, as when the FiO₂, IMV, or PEEP settings are decreased. Assess the patient every hour to ensure that both lungs are aerated by auscultating lung sounds and observing for symmetrical expansion of the chest. Because hyperventilation can occur, patients should be monitored for signs of respiratory alkalosis [2,6,13,26].

A major responsibility is careful monitoring of the patient's vital signs. Because the application of PEEP can result in a decrease in cardiac output, particular attention should be paid to blood pressure, pulse, and urine output. Any time the setting for PEEP is altered, the patient should be re-evaluated. Increasing the amount of PEEP can further compromise venous return, whereas decreasing could result in cardiac overload and pulmonary edema. Often, patients with PEEP have a central venous pressure (CVP) line, a peripherally inserted central venous catheter, or a pulmonary artery catheter, which allows for more accurate assessment of physiologic parameters. Because of the increased positive pressure exerted with PEEP, the patient should be observed for signs and symptoms of pneumothorax [2,6,13,26].

Nursing care of the patient who is mechanically ventilated also includes position change and skin assessment every hour, putting joints through active or passive range of motion exercises every eight hours, and frequent oral care. Patients who are comatose will also require eye care, including use of artificial tears to keep the eyes moist, removal of crusts on lashes and lids with sterile saline or sterile water-soluble lubricants, and/or protection from corneal drying, irritation, or trauma by taping the eyelids closed [2,8,13,26].

Patients will occasionally "fight" or "buck" the ventilator, also referred to as "being out of phase with the ventilator." In these cases, the patient attempts to actively exhale while the ventilator is delivering the inspired volume. This conflict should be corrected because it results in decreased volume delivery and excessively high airway pressures. A bag-valve mask may be used to increase volume delivery gradually and decrease the respiratory rate. Altered inspiratory flow rates may be ordered for the ventilator to correct the situation, or medication may be prescribed to sedate the patient and allow the ventilator to function more efficiently [2,8,13,26].

Another possible complication of prolonged mechanical ventilation is the development of stress-related mucosal damage. This is a broad term that encompasses a spectrum of inflammatory damage to the upper gastrointestinal tract, ranging from superficial lesions to significant gastrointestinal bleeding (e.g., a stress ulcer). The mechanism of the formation of stress ulcers is not entirely understood, but it is believed to be related to a combination of hypersecretion of hydrochloric acid and decreased resistance of the gastric mucosal lining. The resultant gastric irritation may lead to bleeding, so nurses should assess stool and nasogastric drainage for fresh and occult blood. Many ventilated patients receive a proton pump inhibitor for stress ulcer prophylaxis [27].

Gastric dilatation may also occur from introduction of air into the esophagus. This may necessitate the insertion of a nasogastric tube [2,8].

Patients receiving mechanical ventilation require frequent attention and care in an environment with a lot of activity and a high noise level. This may result in sensory overload, so it is important that nursing care be organized to give the patient periods of uninterrupted rest.

Mechanical ventilation can be frightening for patients and their families. Staff members are often so familiar with their routines and equipment that they discount the potential impact on patients and their families. It is important to take time to explain equipment, alarms, and lights. The patient and significant others should be assured that a nurse is always close by and will respond promptly to the patient's calls and alarms. Patients should not be left alone in the room until they appear relatively comfortable with the situation. Be careful not to become so involved with monitoring the equipment and performing the procedures that the patient is forgotten; patients and family members should be given time to express fears and concerns. These patients are acutely ill and may have realistic fears about being dependent on the machine and the possibility of dying [2,6].

Mechanical ventilation limits patient mobility, and patients are confined to their rooms with limited contact with the larger world, which may lead to disorientation. Make a point to interact with the patient frequently and orient him or her to day, time, and place to minimize confusion and prevent anxiety. Lighting can also be controlled to create a day-night change. It can be helpful to keep a large calendar in the room so the patient can remain knowledgeable about passing time. Family members may also bring pictures or other articles to the hospital to personalize the environment. Patients should be encouraged to become actively involved in their care to the extent they are able in order to maintain a sense of control over their lives [2,6,19]. In one study, some patients reported being able to remember things that were said or done while they were sedated and ventilated [28].

When patients require indefinite mechanical ventilation after discharge, they and their family members/caregivers will require instruction. Ancillary healthcare providers may also be needed in the home. The nurse can facilitate proper care by coordinating activities among different departments, such as respiratory therapy, social service, public health nurses, and any other healthcare team members involved [2,5].

Weaning the patient from mechanical ventilation involves reducing physiologic and psychologic dependence on the ventilator. Before weaning, the patient's arterial blood gas values on a liter flow of oxygen should be greater than 40% to 50%.

If the patient is receiving PEEP, it should be no higher than 5 cm; otherwise, it will interfere with the patient's independent inspiratory efforts. Vital capacity should be greater than 15 mL/kg of body weight, as this indicates that the patient is able to move enough air. This measurement can be obtained using a respirometer attached to the end of the patient's endotracheal or tracheotomy tube. Maximum inspiratory effort should also be assessed to determine whether the patient's chest expansion is sufficient to produce negative alveolar pressure and stimulate a deep inspiration. The greater the patient's ability to inhale, the more negative the inspiratory pressure will be. This is assessed by attaching a pressure gauge to the end of the endotracheal or tracheotomy tube and instructing the patient to take in a deep breath. The patient is considered to be ready for weaning with a pressure of -25 to -30 cm. Respiratory rate and minute volume measurements should be taken. The respiratory rate should be at least 12 breaths per minute, but no greater than 20 breaths per minute [6,8,13]. Additional criteria for weaning include a stable chest wall, an acceptable chest x-ray, adequate cardiac output, normal body temperature, adequate nutritional status, and a generally well-rested condition.

Before beginning, the weaning process should be explained to the patient. Two methods used to wean patients are the T-piece and IMV. Regardless of the weaning method employed, the cuff of the endotracheal or tracheotomy tube is usually deflated first. In T-piece weaning, the patient is taken off the ventilator and a T-tube carrying humidified oxygen is attached to the airway. Patients should be encouraged to use the breathing exercises taught to them while they were on the ventilator. Weaning is started during the day and scheduled around medications and activities so the patient is not uncomfortable or interrupted. This also helps to keep the patient on a day/night schedule. The patient should be suctioned prior to disconnection from the ventilator. A semi-Fowler's position will facilitate the weaning process by preventing abdominal contents from pressing on the diaphragm [2,6].

Weaning is usually started with 15 minutes off the ventilator and gradually increased if the patient's respiratory status remains stable. The patient's vital signs should be checked frequently during this period. Indications that weaning is being poorly tolerated include increased respiratory rate and dyspnea, tachycardia, cardiac dysrhythmias, change in mentation, fatigue, and decrease in pulmonary volumes. Arterial blood gas measurements are obtained for objective evidence of how well the patient is independently ventilating [6].

The other method of weaning is via the IMV method. The number of IMV breaths per minute is gradually decreased (without exceeding the patient's tolerance) until the patient is breathing totally spontaneously. The same nursing implications described for T-piece weaning apply [5,6].

The insertion of a chest tube can be painful. If the procedure is not an emergency, analgesics or pain medications should be given 30 minutes prior to tube insertion. It is of utmost importance that the nurse explains the procedure and equipment used. Patients and/or their family should be told that the tube(s) will be placed through the chest wall to drain air, fluid, or both, so the lungs can function normally. The tubes are secured by a dressing and connected to a drainage apparatus.

When chest tubes are inserted at the bedside, the nurse is responsible for obtaining equipment. The equipment may vary among institutions, but generally includes:

Unless contraindicated, the patient is usually placed in a recumbent position for insertion of the chest tube. If the tube is being inserted to remove air (e.g., in the case of pneumothorax), the patient should be supine. Because air rises, the chest tube is inserted anteriorly in the midclavicular line in the second to fifth intercostal space. If the tube is being placed to remove fluid (e.g., for hemothorax), the patient should be placed in a semi-Fowler's position. Because fluid collects in the dependent area, the tube is inserted in the sixth to eighth intercostal space in the midaxillary line. The patient who cannot tolerate a semi-Fowler's position should lie on the unaffected side [8]. For visual landmark placement, the fourth intercostal space is generally at nipple level on men or the level of the inframammary fold on women [8,29]. A chest x-ray is typically completed post-insertion and at regular intervals for to monitor placement and resolution of the space-occupying lesion [31].

Chest tubes are connected to approximately 6 feet of tubing that leads to the collection system, which is placed considerably below the patient's chest in order to take advantage of gravity flow and facilitate removal of air and fluid from the intrapleural space. The tubing should be long enough that it allows the patient to move and turn without pulling. The dependent position and a long tube also prevent the backflow of fluid into the intrapleural space.

Chest tube drainage systems are closed devices. Two types are utilized: wet suction and dry suction systems. However, not all patients who require a chest tube also require suction. A wet suction system controls suction by the level of water in the suction control chamber, normally -20 cm for adults. Less water in the chamber equals less suction.

A dry suction system is similar, but it uses a regulator to adjust the amount of suction instead of a water chamber. The dry suction system also responds to air leaks by delivering consistent and stable suction. To prevent the re-entry of air into the intrapleural space, the distal end of the chest tube should be submerged under water. This seal is a necessary part of any chest drainage unit. During exhalation, the pressure in the lungs forces air out of the pleural space through the tubing and into the water (as shown by bubbling) [8].

There are a number of variations of chest drainage units available. Previously, reusable glass systems were the standard. Now, sterile disposable systems are common. These systems are lightweight, take up a small amount of space, and are not breakable. Disposable systems can have one or multiple chambers, a valve or water seal, and/or water- or dry-suction control.

The Eastern Association for the Surgery of Trauma concludes that there is no evidence to support the routine use of presumptive antibiotics for post-traumatic tube thoracostomy to decrease the incidence of pneumonia or empyema.

(https://tsaco.bmj.com/content/4/1/e000356 Last Accessed: October 16, 2023)

Level of Evidence: Expert Opinion/Consensus Statement

The major objective of nursing care for patients with chest tubes is to facilitate drainage of fluid and air, fostering lung re-expansion. It is imperative to identify which system is being used and why. After insertion of the chest tube, a dressing is applied using sterile technique. Gauze or a hydrocolloid dressing is wrapped around the insertion site, and wide tape is applied to provide an occlusive dressing. This prevents air from entering the intrapleural space. Although the chest tube is sutured in place, further care should be taken to secure the tube when applying the tape. If drainage is present on the dressing, the physician should be notified [8].

Characteristics of the chest tube drainage should be recorded, including amount, color, consistency, and odor. Initially, the drainage characteristics should be noted every 15 to 20 minutes. Persistent drainage of more than 100 mL per hour should be reported. The collection should be labeled with the time, and drainage volumes should be recorded each nursing shift [8].

An important aspect of care for the patient with chest tubes is assessment of the patient's respiratory status. Patients should be questioned about their level of discomfort and any difficulty in breathing. Lung fields should be auscultated to determine if all areas of the lungs are being aerated. Watch for symmetrical expansion of the chest when the patient breathes, and listen for any adventitious breath sounds. The rate, depth, and quality of respirations should be noted and the patient encouraged to cough and deep breathe every hour to facilitate lung re-expansion and prevent complications [8].

It is essential that the seal in the chest drainage unit be maintained to prevent re-entry of air into the pleural space. If a water seal is used, at least 2–2.5 cm of sterile water or normal saline should be placed in the water-seal bottle. The fluid level should be checked frequently and sterile water or saline added to replace water lost to evaporation. It is important that the drainage unit be kept well below the chest level; if any part of the system is lifted above the chest level, fluid may re-enter the pleural space (although most systems now have a one-way valve that prevents air or fluid from entering the chest). When transporting the patient, use a stretcher with a bottom shelf and place the collation unit on the stretcher shelf, keeping the system below the level of the patient's chest. It is recommended that someone familiar with the water-seal system accompany the patient during transport [8].

The water seal can be lost by inadvertently disconnecting or dislodging the tubing. Disconnection should be suspected if one notices an absence of fluctuation in the water-seal bottle or chamber. In the event that a tube becomes disconnected, the end of the disconnected tubing should be cleaned with an alcohol swab and reconnected. The nurse should then ask the patient to cough deeply to remove any excessive air that may have accumulated in the intrapleural space [8].

A chest tube should never be clamped, because a tension pneumothorax can develop if a continuous air leak is present [5,6]. If a chest tube is pulled out or falls out of the intrapleural space, the patient should be asked to exhale forcefully, and the opening should be immediately covered. Ideally, the wound should be covered with gauze or dressing and pressure applied until the tube can be re-inserted. If gauze is not available, the palm of a gloved hand or a sheet can be used. If the patient develops signs and symptoms of a tension pneumothorax, the pressure should be momentarily relieved to allow air to escape [5,6].

Maintaining the patency of the drainage system is necessary to facilitate expansion of the lung, and frequent, systematic observations should be made to determine that the system is patent. This includes checking for loose connections and reinforcing the dressing as needed. All connections should be secured with tape or bands [8].

The water in the seal rises and falls with changes in intrapleural pressure. As the patient inhales, fluid should be pulled up into the water-seal tube or the chest tube, and the level should fall back as the patient exhales. Absence of fluctuation may be caused by an obstructed tube, a disconnected tube, or re-expansion of the lung [8].

Bubbling is normally present in the water-seal chamber during exhalation. However, continuous bubbling during both inspiration and expiration may signal an air leak. The air leak can be from the patient's lung or from an opening in the tubing or collection receptacle. A physician should be notified of any absence of fluctuation or continuous bubbling [5,6,8].

The drainage tubing should be regularly inspected for kinks or dependent loops. Kinking, which can occur along any section of the tubing from the chest tube to the collection device, will obstruct the flow of air or fluid. To prevent kinking at the point of entry into the drainage device, the tubing may be secured to a tongue blade with tape. Dependent (hanging) loops, which allow fluid to accumulate and thus alter the pressure within the system, can be avoided by proper positioning of the tubing. The tube should be coiled flat and should fall in a straight line from the coil to the drainage receptacle. The coiled tubing can be secured to the edge of the bed [5,6].

When suction is applied, the suction control bottle or chamber should be observed for bubbling. Absence of bubbling suggests that sufficient suction is not being applied to the intrapleural space, whether because of an obstructed suction control tube, a leak in the system, an obstructed air inlet, or simply setting the suction too low. Incomplete expansion on one side only is due to increased intrapleural pressure.

Rarely, milking or stripping of the chest tubes may be necessary to prevent the formation of clots or remove clots from the tubing [6]. Evidence to support this practice is scant, and it should only be done if ordered by a physician. The tube should be secured at the incision site to prevent inadvertent dislodgement.

When it is time to discontinue the chest tube, every effort should be made to remove it upon expiration. If the chest tube is removed on inspiration, a pressure gradient develops inside the chest that produces increased intrathoracic pressure, which predisposes the patient to a persistent/recurrent pneumothorax. Many methods can be used to prevent this from occurring. One is to time discontinuation of the tube in synchrony with the patient's breathing, removing it at expiration. Another is to have the patient hold his or her breath or make a seal and blow on their thumb like blowing up a balloon. An occlusive dressing is preferred post-removal. The provider may opt to place a U-stitch around the incision site and tighten it when the tube is discontinued to occlude the wound [29].

As noted, the insertion of a chest tube is a painful, invasive procedure. Explanations and reassurance should be provided for the patient and family members. During the insertion, remain with the patient to provide emotional support. It is helpful to have one or two extra personnel on hand, if possible, to assist with the insertion and support the patient.

Patients with chest tubes may restrict their breathing and movement not only to minimize pain, but because they fear they may dislodge the tube. They should be informed that the tube is secured with sutures and tape. Movement such as turning, coughing, and deep breathing should be encouraged, as this will facilitate re-expansion of the lung. The patient should be told that pain medication is available to decrease discomfort during breathing exercises. Opioids, however, should be avoided or administered judiciously because they can depress the respiratory rate [8].

The collection receptacle should also be explained to the patient. If suction is necessary, patients should be aware that bubbling and some noise are expected. Patients and family members should be given the opportunity to verbalize fears and ask questions regarding the procedure and equipment. Be aware that chest tubes may seem more frightening to visitors than other sorts of tubes, and be prepared to reassure patients that it is the visitor's lack of knowledge, not the patient's situation, that has caused the reaction [8].