Laryngoscopes blades (large adult, small adult, child, infant and newborn) The vast majority of tracheal intubations involve the use of a
viewing instrument of one type or another. The modern conventional laryngoscope consists of a handle containing batteries that power a light and a set of interchangeable
blades, which are either straight or curved. This device is designed to allow the laryngoscopist to directly view the larynx. Due to the widespread availability of such devices, the technique of blind intubation
Fiberoptic laryngoscopes have become increasingly available since the 1990s. In contrast to the conventional laryngoscope, these devices allow the laryngoscopist to indirectly view the larynx. This provides a significant advantage in situations where the operator needs to see around an acute bend in order to visualize the glottis, and deal with otherwise difficult intubations.
Video laryngoscopes are specialized fiberoptic laryngoscopes that use a
digital video camera sensor to allow the operator to view the glottis and larynx on a video monitor. Other "noninvasive" devices which can be employed to assist in tracheal intubation are the
laryngeal mask airway (used as a conduit for endotracheal tube placement) and the
Airtraq.
Stylets An intubating stylet is a malleable metal wire designed to be inserted into the endotracheal tube to make the tube conform better to the upper airway anatomy of the specific individual. This aid is commonly used with a difficult laryngoscopy. Just as with laryngoscope blades, there are also several types of available stylets, such as the Verathon Stylet, which is specifically designed to follow the 60° blade angle of the GlideScope video laryngoscope. The Eschmann tracheal tube introducer (also referred to as a "gum elastic bougie") is specialized type of stylet used to facilitate difficult intubation. This flexible device is in length, 15
French (5 mm diameter) with a small "hockey-stick" angle at the far end. Unlike a traditional intubating stylet, the Eschmann tracheal tube introducer is typically inserted directly into the trachea and then used as a guide over which the endotracheal tube can be passed (in a manner analogous to the
Seldinger technique). As the Eschmann tracheal tube introducer is considerably less rigid than a conventional stylet, this technique is considered to be a relatively atraumatic means of tracheal intubation. The tracheal tube exchanger is a hollow
catheter, in length, that can be used for removal and replacement of tracheal tubes without the need for laryngoscopy. The Cook Airway Exchange Catheter (CAEC) is another example of this type of catheter; this device has a central
lumen (hollow channel) through which
oxygen can be administered. Airway exchange catheters are long hollow catheters which often have connectors for jet ventilation, manual ventilation, or oxygen insufflation. It is also possible to connect the catheter to a capnograph to perform respiratory monitoring. The lighted stylet is a device that employs the principle of
transillumination to facilitate blind orotracheal intubation (an intubation technique in which the laryngoscopist does not view the glottis).
Tracheal tubes operations such as
VATS lobectomy A tracheal tube is a catheter that is inserted into the trachea for the primary purpose of establishing and maintaining a patent (open and unobstructed) airway. Tracheal tubes are frequently used for
airway management in the settings of general anesthesia, critical care, mechanical ventilation, and emergency medicine. Many different types of tracheal tubes are available, suited for different specific applications. An endotracheal tube is a specific type of tracheal tube that is nearly always inserted through the mouth (orotracheal) or nose (nasotracheal). It is a
breathing conduit designed to be placed into the airway of critically injured, ill or anesthetized patients in order to perform mechanical
positive pressure ventilation of the lungs and to prevent the possibility of aspiration or airway obstruction. The endotracheal tube has a fitting designed to be connected to a source of pressurized gas such as oxygen. At the other end is an orifice through which such gases are directed into the lungs and may also include a balloon (referred to as a cuff). The tip of the endotracheal tube is positioned above the
carina (before the trachea divides to each lung) and sealed within the trachea so that the lungs can be ventilated equally. A tracheostomy tube is another type of tracheal tube; this curved metal or plastic tube is inserted into a tracheostomy
stoma or a cricothyrotomy incision. Tracheal tubes can be used to ensure the adequate
exchange of oxygen and
carbon dioxide, to deliver oxygen in higher concentrations than found in air, or to administer other gases such as
helium,
nitric oxide, nitrous oxide,
xenon, or certain volatile anesthetic agents such as
desflurane,
isoflurane, or
sevoflurane. They may also be used as a route for administration of certain medications such as
bronchodilators,
inhaled corticosteroids, and drugs used in treating
cardiac arrest such as
atropine,
epinephrine,
lidocaine and
vasopressin. Originally made from
latex rubber, most modern endotracheal tubes today are constructed of
polyvinyl chloride. Tubes constructed of
silicone rubber, wire-reinforced silicone rubber or
stainless steel are also available for special applications. For human use, tubes range in size from in internal diameter. The size is chosen based on the patient's body size, with the smaller sizes being used for infants and children. Most endotracheal tubes have an inflatable cuff to seal the tracheobronchial tree against leakage of respiratory gases and pulmonary aspiration of gastric contents, blood, secretions, and other fluids. Uncuffed tubes are also available, though their use is limited mostly to children (in small children, the
cricoid cartilage is the narrowest portion of the airway and usually provides an adequate seal for mechanical ventilation). In addition to cuffed or uncuffed, preformed endotracheal tubes are also available. The oral and nasal RAE tubes (named after the inventors Ring, Adair and Elwyn) are the most widely used of the preformed tubes. There are a number of different types of
double-lumen endo-bronchial tubes that have endobronchial as well as endotracheal channels (Carlens, White and Robertshaw tubes). These tubes are typically
coaxial, with two separate channels and two separate openings. They incorporate an endotracheal lumen which terminates in the trachea and an endobronchial lumen, the distal tip of which is positioned 1–2 cm into the right or left mainstem bronchus. There is also the Univent tube, which has a single tracheal lumen and an integrated
endobronchial blocker. These tubes enable one to ventilate both lungs, or either lung independently. Single-lung ventilation (allowing the lung on the operative side to collapse) can be useful during
thoracic surgery, as it can facilitate the surgeon's view and access to other relevant structures within the
thoracic cavity. The "armored" endotracheal tubes are cuffed, wire-reinforced silicone rubber tubes. They are much more flexible than polyvinyl chloride tubes, yet they are difficult to compress or kink. This can make them useful for situations in which the trachea is anticipated to remain intubated for a prolonged duration, or if the neck is to remain flexed during surgery. Most armored tubes have a Magill curve, but preformed armored RAE tubes are also available. Another type of endotracheal tube has four small openings just above the inflatable cuff, which can be used for suction of the trachea or administration of intratracheal medications if necessary. Other tubes (such as the Bivona Fome-Cuf tube) are designed specifically for use in laser surgery in and around the airway.
Methods to confirm tube placement No single method for confirming tracheal tube placement has been shown to be 100% reliable. Accordingly, the use of multiple methods for confirmation of correct tube placement is now widely considered to be the
standard of care. Such methods include direct visualization as the tip of the tube passes through the glottis, or indirect visualization of the tracheal tube within the trachea using a device such as a bronchoscope. With a properly positioned tracheal tube, equal bilateral
breath sounds will be heard upon
listening to the chest with a stethoscope, and no sound upon listening to the area
over the stomach. Equal bilateral rise and fall of the chest wall will be evident with ventilatory excursions. A small amount of
water vapor will also be evident within the lumen of the tube with each exhalation and there will be no gastric contents in the tracheal tube at any time. Ideally, at least one of the methods utilized for confirming tracheal tube placement will be a
measuring instrument. Waveform
capnography has emerged as the
gold standard for the confirmation of tube placement within the trachea. Other methods relying on instruments include the use of a
colorimetric end-tidal carbon dioxide detector, a self-inflating esophageal bulb, or an esophageal detection device. The distal tip of a properly positioned tracheal tube will be located in the mid-trachea, roughly above the bifurcation of the carina; this can be confirmed by
chest x-ray. If it is inserted too far into the trachea (beyond the carina), the tip of the tracheal tube is likely to be within the
right main bronchus—a situation often referred to as a "right mainstem intubation". In this situation, the left lung may be unable to participate in ventilation, which can lead to
decreased oxygen content due to
ventilation/perfusion mismatch. ==Special situations==