Anesthetic Equipment and Monitoring
Full content is reserved for members.
Anesthesiologists spend a significant portion of their professional time in operating rooms and are responsible for protecting both patients and personnel from a multitude of dangers, some of which are unique to this environment. Consequently, the anesthesiologist must often ensure the proper functioning of medical gases, manage fire prevention, oversee electrical safety, and address environmental factors like temperature and ventilation. This chapter describes the major operating room features and potential hazards that are of special interest to anesthesiologists.
Culture of Safety
The operating room is perceived as a safe environment, but errors can occur unless the entire team remains vigilant. The most effective way to prevent harm is by creating a culture of safety that identifies and halts unsafe acts before they cause harm. A primary tool in fostering this culture is the surgical safety checklist, which must be used prior to incision in every case.
* Checklists, often derived from the World Health Organization (WHO) surgical safety checklist, are most effective when used interactively, with all team members focused.
* Rather than reading the entire list and asking for general agreement, a better method is to elicit a specific response after each checkpoint (e.g., "Does everyone agree this patient is John Doe?").
* Optimal checklists address key components and are completed efficiently (e.g., in less than 90 seconds).
* Correctly implemented checklists reduce preventable complications such as wrong-site surgery, retained foreign objects, and medication errors in patients with known allergies. Anesthesia providers have historically been leaders in patient safety and should proactively champion the use of checklists.
img
Medical Gas Systems
The common medical gases in the OR are oxygen, nitrous oxide, air, and nitrogen. Vacuum exhaust for waste anesthetic gas disposal (WAGD) and surgical suction are also integral to the system. The anesthesia provider must understand the sources and delivery of these gases to prevent or detect depletion or misconnection, as malfunctions (especially with oxygen) can endanger patients. System design follows standards such as NFPA 99 in the United States.
SOURCES OF MEDICAL GASES
Oxygen
Medical-grade oxygen (99% or 99.5% pure) is manufactured by fractional distillation of liquefied air. It is stored either as a compressed gas or as a refrigerated liquid.
- Cylinder Banks: Smaller hospitals often use two separate banks of high-pressure H-cylinders connected by a manifold. This manifold reduces the cylinder pressure (approx. 2000 psig) to the line pressure (55 ± 5 psig) and automatically switches banks when one is exhausted.
- Liquid Oxygen Storage: Large hospitals find it more economical to store oxygen as a liquid, which requires it to be kept below its critical temperature of -119°C. A reserve supply (either a smaller liquid tank or compressed gas cylinders) is also maintained.
- Emergency Supply: Anesthesiologists must always have an emergency E-cylinder of oxygen available. As oxygen is expended from an E-cylinder, the pressure falls in proportion to its content. Oxygen E-cylinders have a pin index safety system to prevent incorrect attachment and a Wood's metal plug (a pressure-relief valve) that ruptures at 3300 psig to prevent explosion in a fire.
A pressure of 1000 psig in an oxygen E-cylinder indicates it is approximately half full, containing about 330 L of oxygen. A full E-cylinder contains 625-700 L at a pressure of 1800-2200 psig.
Nitrous Oxide
Nitrous oxide is typically stored in large H-cylinders. Because its critical temperature (36.5°C) is above room temperature, it can be kept liquefied without refrigeration. In an E-cylinder, it also exists in a liquid state.
- As long as liquid nitrous oxide remains in the cylinder (at a constant temperature of 20°C), the pressure gauge will read 745 psig. The pressure only begins to fall after the liquid is exhausted, at which point only about 400 L of gas remains.
- Like oxygen cylinders, $N_2O$ cylinders have a Wood's metal plug to prevent explosion.
- Vaporization of the liquid $N_2O$ consumes energy (latent heat of vaporization), which cools the cylinder. At high flow rates, this can cause frost to form on the tank and may even freeze the pressure regulator.
end
The pressure gauge on a nitrous oxide cylinder is not a reli…
Medical gases are delivered from the central supply source to the operating room via a network of seamless copper pipes. This system is engineered so that the pressure drop across the entire network never exceeds 5 psig. In the operating room, these de…
TEMPERATURE
Operating room temperatures often feel uncomfortably cold to conscious patients and providers, but surgeons and scrub nurses must stand under hot surgical lights for extended periods. The comfort of personnel must be balanced with patient care. For adult patients, ambient room temperature should generally be maintained between 68°F (20°C) and 75°F (24°C). The impact of environmental temperature on the patient's core temperature must be monitored, as h…
The extensive use of electronic medical equipment exposes both patients and healthcare personnel to the risk of electrical shock and electrocution. Anesthesia providers must have a clear understanding of electrical hazards and the protective systems in place within the operating room.
THE RISK OF ELECTROCUTION
An electrical shock occurs when a person's body contacts two conductive materials at different voltage potentials, completing a circuit. Typically, one contact point is a live 120-…
Electrosurgical units (ESUs), also known as electrocautery, are a ubiquitous source of electrical current in the operating room. They function by generating an ultrahigh-frequency electrical current that passes from a small active electrode (the cautery tip) through the patient. The current then exits the patient's body via a
M…
FIRE PREVENTION & PREPARATION
Surgical fires are relatively rare but almost entirely preventable. Unlike complex medical complications, fires are a product of simple physical and chemical properties. A fire is guaranteed to occur given the correct combination of factors, but it can be eliminated by understanding the basic principles of fire risk.
The simple combination required for any fire is known as the **fire triad** or **fire triangle**, which is composed of:
1. Fuel (e.g., alcohol-based prep,
2…
Crew Resource Management (CRM) is a concept originally developed in the aviation industry to promote teamwork and reduce human error. Its goal is to empower any team member to intervene or question any situation perceived as unsafe. In the operating room, this model is highly beneficial, as i…
In the United States, the Centers for Medicare and Medicaid Services (CMS) is a primary driver of mandated policies and procedures within healthcare facilities. To reduce fraudulent claims and care disparities, CMS requires certification from an accrediting agency, such as The Joint Commission (TJC) or…
Breathing systems serve as the final conduit for delivering anesthetic gases to the patient, linking the patient to the anesthesia machine. A wide variety of circuit designs have been developed, each with different characteristics regarding efficiency, convenience, and complexity. This chapter reviews the most important breathing systems, including insufflation, draw-over…
The insufflation and draw-over systems present several disadvantages, including poor control of inspired gas concentration (and thus depth of anesthesia), mechanical drawbacks during head and neck surgery, and significant operating room pollution with waste gas. The Mapleson systems were designed to solve some of these problems by incorporating additional componen…
Mapleson circuits are advantageous for their simplicity, light weight, and low cost. Their efficiency is measured by the fresh gas flow (FGF) required to prevent the rebreathing of carbon dioxide. Because these circuits lack unidirectional valves and $CO_2$ absorption, rebreathing is prevented entirely by using an adequate FGF to flush exhaled gas (co…
While Mapleson circuits solve some problems of insufflation and draw-over systems, they require high fresh gas flows to prevent $CO_2$ rebreathing. This high flow results in wasted anesthetic agent, operating room pollution, and significant loss of patient heat and humidity. To address these issues, the circle system incorporates additional components, most notably a carbon dioxide absorber, which allows for the r…
Optimization of Circle System Design
The arrangement of components in a circle system is critical for efficiency and safety. The preferred, modern configuration is as follows:
- Unidirectional Valves: These are placed relatively close to the patient to prevent backflow into the inspiratory limb. However, they are *not* placed in the Y-piece itself, as this makes it difficult to confirm their proper function intraoperatively.
- Fresh Gas Inlet: The FGF is placed between the absorber and the inspiratory va
- A…
Resuscitation bags (commonly known as AMBU bags or bag-mask units) are frequently used for emergency ventilation due to their simplicity, portability, and ability to deliver almost 100% oxygen. These systems are fundamentally different from Mapleson or circle sy…
No piece of equipment is more intimately associated with anesthesiology than the anesthesia machine. The anesthesiologist uses this device to control the patient's ventilation, deliver precise oxygen concentrations, and administer inhalation anesthetics. Proper functioning is critical for patient safety. Modern machines, often called **anesthesia workstations**, incorporate numerous built-…
Pressure Regulators
The high and variable pressure of gas in cylinders (e.g., ~1900 psig for $O_2$) makes flow control difficult and dangerous. To ensure safety, the machine uses a pressure regulator to reduce the cylinder gas pressure to a constant, lower pressure of approximately 45 to 47 psig. As this is slightly lower than the pipeline pressure of 50 psig, it allows the machine to preferentially use the pipeline supply even if a cylinder is left open. After passing through their respective regulators,
O…
Volatile anesthetics (e.g., sevoflurane, desflurane, isoflurane) must be converted from a liquid to a gas (vaporized) before being delivered to the patient. Vaporizers are concentration-calibrated devices that precisely add a known concentration of volatile anesthetic agent to the combined fresh gas flow. They must be located in the low-pressure circuit, between the flowmeters and the common gas outlet. To prevent the lethal error of administering more than one agent at a time, all machines must have an **interlocking** or exclusion device that prevents the concurrent use of more than one vaporizer.
A. Physics of Vaporization
In a closed container, molecules of a volatile li…
In contrast to the multiple gas inlets, the anesthesia machine has only one **common gas outlet** (or "fresh gas outlet"). This single port delivers the final mixtu…
In adults, the breathing system most commonly used with anesthesia machines is the circle system. It is critical to understand that the gas composition at the common gas outlet (which is precisely controlled) can be significantly different from the gas composition within the breathing circuit itself. The circuit's gas composition is affected by numerous other factors, including the patient's anesthetic uptake, minute ventilation, total fresh gas flow, the volume of the breathing circuit, and the presence of any leaks. Using high gas flow rates during induction and emergence can minimize these discrepancies. Measurement
O…
All modern anesthesia workstations are equipped with a mechanical ventilator. Historically, operating room ventilators were simpler than their intensive care unit (ICU) counterparts. This distinction has become blurred as technology has advanced, and sicker patients require ICU-level ventilation in the OR. Ventilators generate gas flow by creating a pressure gradient between the proximal airway and the alveoli. Their function is best understood by examining the four phases of the ventilatory cycle.
Phases of the Ventilatory Cycle
A. Inspiratory Phase
During inspiration, the ventilat…
Monitoring airway pressure and volume is essential for assessing lung mechanics and ensuring safe ventilation. The shape of the breathing-circuit pressure waveform provides critical diagnostic information, and many modern machines display this graphically.
Peak vs. Plateau Pr…
A. Ventilator-Fresh Gas Flow Coupling
A critical concept in traditional double-circuit ventilators is that the ventilator spill valve is closed during inspiration. Because of this, any fresh gas flow (FGF) from the machine's common gas outlet during the inspiratory cycle will contribute to and *add to* the tidal volume being delivered to the patient. This is known…
Waste-gas scavengers are systems designed to dispose of gases that have been vented from the breathing circuit, primarily from the APL valve (during manual ventilation) and the ventilator spill valve (during mechanical ventilation). This disposal is critica…
Misuse or malfunction of anesthesia gas delivery equipment can cause major morbidity or mortality. A routine inspection of anesthesia equipment before each use increases operator familiarity and confirms proper functioning. The U.S. Food and Drug Administration (FDA) has made available a generic checkout procedure for anesthesia machines and breathing systems, which should be modified as necessary for specific equipment and manufacturer recommendations.
Some anesthesia machines provide an automated system check that requires a variable amount of human intervention. Thes…
ARTERIAL BLOOD PRESSURE
The rhythmic ejection of blood from the left ventricle into the arterial tree results in pulsatile arterial pressures. The peak pressure during ventricular contraction is the **systolic arterial blood pressure (SBP)**, and the lowest pressure during diastolic relaxation is the **diastolic blood pressure (DBP)**. The difference between these two is the **pulse pressure**. The time-weighted average of arterial pressures during a si…
In addition to intermittent cuff-based methods, two techniques allow for continuous, beat-to-beat noninvasive blood pressure monitoring.
E. Arterial Tonometry
Arterial tonometry measures beat-to-beat pressure by sensing the force required to partially flatten a superficial artery that is supported by an underlying bony structure (e.g., the radial artery). A…
A. Selection of Artery for Cannulation
Several peripheral arteries are available for percutaneous catheterization, with the choice depending on patient factors and collateral circulation.
- 1. Radial Artery: This is the most commonly cannulated artery. Its popularity stems from its superficial location and substantial collateral blood flow, as the ulnar artery (which is typically larger)A…
While intraarterial cannulation is considered the optimal technique for continuous beat-to-beat blood pressure measurement, its accuracy is entirely dependent on the **dynamic characteristics** of the monitoring system (the catheter, tubing, stopcocks, and transducer). False readings from a poorly functioning system can lead to inappropriate and dangerous therapeutic
S…
Indications & Contraindications
Continuous intraoperative monitoring of the electrocardiogram (ECG) is mandatory for all patients undergoing anesthesia. This is a required component of the American Society of Anesthesiologists (ASA) standards for basic anesthetic monitoring. There are no contraindications to its use.
Techniques & Complication…
Indications
Central venous pressure (CVP) monitoring is indicated for several reasons, including:
- Assessment of intravascular volume status and right-sided cardiac filling pressures.
- Administration of caustic drugs (e.g., vasopressors, chemotherapy, hyperosmolar solutions) that require rapid dilution in a large central vein.
- Aspiration of air emboli (a risk in certain procedures, such as sitting neurosurgery).
- Access to the central circulation for placement of pulmonary artery catheters or transvenous pacing wires.
- Inadequate peripheral intrave…
Indications
The pulmonary artery (PA) catheter, or Swan-Ganz catheter, was a cornerstone of hemodynamic monitoring in the 1970s. Its primary advantage was the ability to measure the pulmonary capillary occlusion pressure (PCOP) or "wedge" pressure. The PCOP is used as an estimate of left atrial pressure and, by extension, left ventricular end-diastolic pressure (LVEDP). This value was used as a surrogate for left ventricular preload.
By combining PCOP with cardiac output (CO) measurements (also ob…
Indications
Measurement of cardiac output (CO) to permit the calculation of stroke volume (SV) and systemic vascular resistance (SVR) was one of the primary reasons for pulmonary artery (PA) catheterization. Today, numerous alternative, less invasive methods are available to estimate ventricular function and guide goal-directed fluid therapy.
Techniques & Complications
A. Thermodilution
This is the classic method used with a PA catheter. A known quantity (e.g., 2.5, 5, or 10 mL) of cold fluid (iced or room temperature saline) is injected into the right atrium via the proximal (CVP) port. This cold injectate mixes with the blood and travels
There are no more powerful tools for the perioperative diagnosis and assessment of cardiac function than transthoracic (TTE) and transesophageal echocardiography (TEE). TEE, in particular, has become an ideal option in the operating room as it provides continuous, detailed visualization of the heart when access to the chest is limited.
The primary applications of perioperative echocardiography include:
- Diagnosis of hemodynamic instability (e.g., systolic/diastolic heart failure, hypovolem…
This chapter examines the essential noncardiovascular monitoring techniques used perioperatively, including the monitoring of respiratory gas exchange, neurological condition, neuromuscular transmission, and body…
Indications & Contraindications
Pulse oximeters are mandatory monitors for any anesthetic procedure, including cases performed under moderate sedation. There are no contraindications to their use.
Techniques & Complications
Pulse oximeters noninvasively measure the oxygen saturation in arterial blood (Spo2) by combining the principles of oximetry and plethysmography. A se…
Indications & Contraindications
The determination of end-tidal $CO_2$ ($ETco_2$) concentration to confirm adequate ventilation is **mandatory** during all anesthetic procedures. Capnography is a powerful diagnostic tool:
- It is the most rapid and reliable method to confirm tracheal intubation and rule out esophageal intubation.
- It p…
Indications
Analysis of anesthetic gas concentrations (both inspired and expired) is essential during any procedure requiring inhalation anesthesia to ensure adequate delivery and prevent overdose. There are no contraindications to…
ELECTROENCEPHALOGRAPHY
Indications & Contraindications
The electroencephalogram (EEG) is a recording of electrical potentials generated by cells in the cerebral cortex. It is occasionally used during specific surgical procedures to monitor brain function. Indications include:
- Cerebrovascular surgery (e.g., carotid endarterectomy): To confirm the adequacy of cerebral oxygenation and detect ischemia during cross-clamping.
- Cardiovascular surgery (e.g., deep hypothermic circulatory arres…
EVOKED POTENTIALS
Indications
Intraoperative monitoring of evoked potentials (EPs) is indicated for surgical procedures associated with a high risk of neurological injury. This monitoring noninvasively assesses the functional integrity of neural pathways (sensory or motor) by measuring the electrophysiological responses to stimulation. The goal is to detect neural damage early enough to allow…
Indications
The temperature of patients undergoing anesthesia should be monitored during all but the shortest procedures. Postoperative temperature is increasingly used as a measurement of anesthesia quality. Detecting and managing temperature changes is cr…
Indications
Urinary bladder catheterization (e.g., with a Foley catheter) is the most reliable method for monitoring urinary output intraoperatively. Catheterization is c…
Indications
Patient sensitivity to neuromuscular blocking agents (NMBAs) varies significantly. Therefore, the neuromuscular function of **all patients** receiving intermediate- or long-acting NMBAs must be monitored. Peripheral nerve stimulation is also helpful to detect the onset of paralysis during induction and to assess the adequacy of reversal at the end of the case.