Blood Pressure Without a Cuff

Pulse characteristics are an unreliable sign—and “should be used only as a last resort.”⁵¹ Originally, the advanced trauma life support (ATLS) course taught that systolic blood pressure can be estimated from whether radial (>80 mm Hg), femoral (70 to 80 mm Hg), or carotid (60 to 70 mm Hg) pulses are palpable. This tends to overestimate the patient’s blood pressure. Although the radial pulse always disappears before the femoral, which always disappears before the carotid, most patients’ actual BP is lower than that predicted by these guidelines. But that, by itself, is useful information in a crisis.¹⁵

Although an exact BP measurement cannot be obtained, patients with cool extremities compared with those of other patients have hypoperfusion. This can be localized to one extremity, but if it is located in multiple extremities—especially in both an arm and a leg—checking palpable temperature is an effective diagnostic technique. These patients have lower cardiac indexes, lower pH, lower bicarbonate levels, lower mixed venous oxygen saturation, and higher lactate levels.⁴² A cold or dusky sole of a neonate’s foot can indicate one or all of the following: hypothermia, hypoxemia, or hypotension.¹⁴

Blood Pressure Without a Stethoscope

Because it may be hard to auscultate BP when transporting patients by air or in a noisy ambulance, palpate the systolic pressure. If done carefully, this method is as accurate as using a stethoscope. Alternatively, use a pulse oximeter by obtaining a good waveform on a finger, inflating the sphygmomanometer until the waveform disappears, and then slowly deflating the cuff until the waveform reappears. The cuff measurement that reappears is the systolic pressure.⁵⁰

Wrist and Calf Blood Pressure Measurements

To be accurate, a BP cuff must be the correct size for the arm. It should cover two-thirds of the length of the upper arm. A BP cuff that is too small causes an abnormally high BP reading; one that is too large results in an abnormally low reading. If you do not have a cuff that fits the arm correctly, move it to a location where it fits properly.

Place a BP cuff on the patient’s forearm (Figure 23-2) or ankle (Figure 23-3) to obtain better access during patient transport (1) with very obese patients on whom the standard adult cuff is too small, (2) for adults when only a child’s-size cuff is available, (3) to avoid periodically occluding an arteriovenous fistula (e.g., dialysis patients) or intravenous (IV) line, (4) or to avoid compressing an area with traumatic injuries.

FIGURE 23-2 Blood pressure cuff on forearm.

FIGURE 23-3 Blood pressure cuff on calf above ankle.

BP cuffs at these sites produce the same or nearly the same mean and diastolic pressure readings, but the systolic pressures vary. Use the mean BP with a forearm or calf BP cuff. (Calculate this by multiplying the diastolic pressure by 2 and adding the systolic pressure. Then divide the result by 3. Alternatively, take one-third of the difference between the systolic and the diastolic pressures, and add this number to the diastolic pressure.)⁴⁰

Volume Measurement

Volume measurements are used to determine the outputs of urine, blood, and other secretions, and to measure fluids and medications. To obtain an accurate volume measurement, use kitchen measuring devices or food containers that have their volume indicated on the label. Generally, they only need to be cleaned of food or whatever else they previously contained. Sterilize the measuring container only if the specimen also has to go to the laboratory or will be used to measure injectable medications. Measuring containers for items that will be taken orally need to be “potable clean,” meaning that one could safely drink from them.

Ear to Patient

If no other option is available, use the method that was common before Laennec invented the stethoscope: put one ear directly against the chest, heart, or abdomen. The sound quality will not be as good as through a stethoscope, but one can get a general idea of cardiac rhythm, abnormal chest sounds, and bowel sounds. Putting one’s ear on an infant’s chest is the fastest and most accurate method for assessing the presence of cardiac activity.

Improvised Standard Stethoscopes

Laennec-type stethoscopes can easily be fashioned by using rolled paper or, even better, a hollow wooden tube, such as bamboo. The cardboard tube from toilet paper or paper towels also works well. When one end is placed on a patient’s chest and the clinician’s ear is at the other end, one can hear the heartbeat clearly. This, of course, depends on ambient noise and the patient’s body habitus. Use any hollow tube, including short lengths of garden hose, ivory or wood tubes, and metal pipes, as a monaural stethoscope.

A simple way to construct a slightly more sophisticated stethoscope is to attach a funnel to two pieces of tubing as shown in Figure 23-9. The juncture of IV tubing works well as a T-tube connector. Put the tube ends directly in your ears, or fashion earpieces as described in Stethoscope Earpiece, later.

FIGURE 23-9 Improvised stethoscope.

Precordial Stethoscope

One very useful monitor during patient transport or procedural sedation is a precordial stethoscope. Taped to the patient’s chest, a precordial stethoscope provides the clinician with continuous assessment of the patient’s audible heart rate and rhythm and breath sounds. Only one earpiece is normally used so that the caregiver can also monitor everything around him or her. In adults, place the stethoscope over the midsternum, in the suprasternal notch, in the perilaryngeal area, or in the axilla. In infants, place the stethoscope to the left chest so that both the heartbeat and breath sounds can be heard. Several improvised methods will produce a workable precordial stethoscope.

The quickest way to make a precordial stethoscope is to attach a piece of rubber tubing (that goes in the clinician’s ear) to the top of a screw-top plastic bottle that has a narrow, tapered opening, such as a ketchup/mayonnaise dispenser. Alternatively, cut off the tapered end of a rubber bulb suction syringe or stethoscope head, if one is available.^16,77

A slightly more complex method is to make a precordial stethoscope from a 20-mL syringe, a 3-way stopcock, IV tubing, and an earpiece (Figure 23-10). Cut the 20-mL syringe 2.5 cm (1 inch) from the infusion end (see Figure 23-10, A). Then, smooth the edges with a file, and place adhesive tape around the cut end of the syringe. Remove the plunger’s rubber sealer (see Figure 23-10, B), cut a large hole in its center (see Figure 23-10, C), and insert the rubber piece into the small piece cut off the syringe barrel (see Figure 23-10, D). After connecting this to a three-way stopcock, connect the stopcock to IV tubing (or other tubing) and then to an earpiece (see Figure 23-10, E).³²

FIGURE 23-10 Improvised precordial stethoscope.

Esophageal Stethoscope

Another way to simultaneously monitor respirations and cardiac rhythm in austere situations and during transport is to use an esophageal stethoscope. Make an esophageal stethoscope from a rubber glove, a nasogastric (NG) tube, suture, and a regular stethoscope. Cut a finger off of the glove, and tie the finger over the end of the NG tube (Figure 23-11). Remove the bell from the stethoscope. Pass the NG tube approximately halfway down the esophagus, and connect the proximal end to the end of the stethoscope. The NG tube can also be passed through the nose.¹⁷

FIGURE 23-11 Making an esophageal stethoscope.

Hearing Aid

When necessary, substitute a stethoscope for a patient’s hearing aid during an examination. Put the earpieces in the patient’s ears and talk into the diaphragm. Unfortunately, this only works, as do hearing aids, for patients with specific types of hearing loss.

Stethoscope Earpiece

To replace a stethoscope earpiece, use the nipple from a baby bottle or pacifier, or the rubber bulb from a medicine or an eye dropper (Figure 23-12). Make the normal pinhole opening in the nipple slightly larger, and tie the nipple in place on the stethoscope. Cut the nipple so that only the distal 1 to 2 cm (0.4 to 0.8 inch) of the rubber piece is used.⁴⁰

FIGURE 23-12 Earpieces for a stethoscope.

Standard Precautions

In an austere environment the basic protective gear used for standard or universal precautions often must be made rather than purchased.

Gowns

A plastic garbage bag with head and arm holes cut out is the simplest waterproof gown, and can be enhanced with arm pieces cut from another bag and stapled or taped in place.

Although not waterproof, a sheet cut like a poncho will also work. Fold a flat sheet so that one-third is doubled over to form the arms. In the center of the folded edge, cut out a hole large enough for the head to pass through. The sleeve is fashioned by cutting slits on both sides of the sheet, midway down the folded section. The slits should extend to the approximate sites of the axillae (Figures 23-13 and 23-14). Once the patient dons the gown, the arms can be secured with safety pins, staples, or tape (Figure 23-15). The large pieces are wrapped around the back under the arms, and the flap on the back makes a tie for the gown. (Depending on the person’s girth, the tie may also need to be pinned.)^55,40

FIGURE 23-13 Improvised surgical/patient gown, Step 1.

FIGURE 23-14 Improvised surgical/patient gown, Step 2.

FIGURE 23-15 Improvised surgical/patient gown, completed.

Caps and Masks

Masks are useful to protect both the examiner and patients against particulate matter, virulent organisms, and nauseating smells (tincture of benzoin on one’s mask covers up most bad smells). Caps protect patients’ wounds from the examiner’s hair. The most basic masks are towels or a cloth held to the mouth and nose, either with one’s hand or tied in place.

Make an improvised surgical mask and cap from a piece of cloth about 46 × 31 cm (18 × 12 inches). Cut a 10-cm (4-inch) narrow oval to fit over the eyes, about 12.5 cm (5 inches) from one end. The cloth should allow a person to breathe through it as easily as is done through a normal surgical mask. Attach a long piece of tape, extending over the edges of the material, at both sides of the slit. Also attach a long piece of tape to the bottom of the short end. Adjust the slit over the eyes, flip the long piece of material over the head for a cap, and then tie both pieces of the tape behind the neck (Figure 26-16). Cover your head with a long cloth or towel (Figure 23-17) and pin or tape it to the nape of your neck to make a simple cap.^56,40

FIGURE 23-16 Improvised cap-mask.

FIGURE 23-17 Improvised cap.

Eye Protection

Put tape around the edges of standard eyeglasses to help to protect the eyes from splattered blood and fluids. An alternative is to wear ski or woodworking goggles—separately or over eyeglasses.

Booties

Make waterproof booties from a large plastic bag. Cut it open so that it lays flat. From that piece, for a standard-sized foot, cut out a portion that is as long as the distance from the foot to the knee and as wide as three lengths of the foot. Make them larger if longer booties are needed, such as in a bloody procedure or when caring for a victim of trauma. Secure them on the foot (not too tight) with duct tape. Clear plastic bags can also work. Cut open as many as needed and tape them to cover the shoes. When using either type of plastic bootie, but especially those made from clear plastic bags, use tape on the bottom to prevent slipping.⁴⁰

Dressings

Most clean, closed wounds do not need a dressing. Wounds without dressings permit easier inspection for infection or dehiscence, eliminate a moist, possibly anaerobic, space over the wound, and make it much easier to keep the wound clean. Have the patient clean the wound with soap and water.

Bandages

Bandages hold dressings in place. If there is a dressing, there is no need for a bandage. The most expedient bandages are torn from expendable pieces of cloth—often clothing. If no cloth bandage is available, use duct tape to secure a dressing after first shaving the area to help the dressing adhere and reduce pain on removal. Poke holes in the tape (especially thick adhesives, such as duct tape) to reduce moisture and allow fluids and sweat to escape. Clean the skin with soap and water or alcohol to remove oils. To make an adhesive dressing, cover a small square of dressing with a piece of tape. If you need to see the wound but still want it covered, make a transparent bandage from clear plastic wrap (e.g., Saran Wrap) or a piece of clear plastic bag with its edges affixed to the skin with tape or cyanoacrylate glue.⁴⁰

A pressure bandage over dressings, used when there is significant seepage or concern about hematoma development, is most easily constructed from an elastic bandage, a bungee cord (use only over fabric stiff enough to distribute the cord’s force), or the elastic from a piece of clothing or equipment.

Venipuncture Tourniquet

A rubber glove (sterile or unsterile, but “stretchy”) works well as a venous tourniquet when starting IV lines or drawing blood. Even better, cut the wrist portion off of a surgical glove and slip it over the arm (or an infant’s head).⁶⁰

Needles

When necessary, use needles for injection as IV needles. Note, however, that they may be more difficult to thread into a vein, because injection needles tend to puncture the vessel wall rather than slide in as does the plastic-coated needle on a catheter. Take care when securing an injection needle, using an arm board or generous bandaging so that the needle does not perforate the vessel.

Saline Locks

To quickly make a saline lock, slip the rubber end of the plunger from a 2- or 3-mL disposable syringe over the end of an IV catheter (Figure 23-18). This also works on a straight needle if it needs to be used as an IV catheter. Simply fill the catheter with saline (or heparin) as would normally be done.⁴⁰

FIGURE 23-18 Improvised saline lock.

Intravenous Tubing

One way to adjust IV flow rates is to wrap a small piece of malleable metal (e.g., heavy aluminum foil) around the tubing. Tighten it to the tubing to achieve the desired flow rate.

Pressure for Intravenous Fluids/Blood Bags

Apply external pressure to IV bags so that, especially when patients must be transported, the pressurized IV bag can simply lie on or next to the patient. Ways to increase the IV or blood bags’ external pressure include inflating a blood pressure cuff around them, and wrapping them with an elastic bandage, a belt (“stretchy” if possible), nylon stockings, a rope, or similar materials. The IV bag can also be placed under an adult patient; body pressure keeps the IV flowing.

Suture Needles

To make a “swaged” suture needle from a hypodermic needle, first pass the suture through the needle from the sharp end. When the end of the suture appears, hold it in place and break off the hub by repeatedly bending it (Figure 23-19). Then pull the suture through the needle so that only a small amount remains within the needle. Finally, crimp the “hub” end of the needle to fix the suture in place.³¹ Do this either at the patient’s bedside or prepare several in advance, wrapping the sutures around a piece of cardboard and autoclaving them en masse.⁷⁵ Newer safety needles may make this process difficult.

FIGURE 23-19 Improvised swaged suture.

Boiling

The best way to disinfect equipment in austere environments is to boil it (100° C [212° F] for 10 to 30 minutes at sea level) in clean water, with or without soap. The time starts when the water has come to a full boil. The temperature at which water boils decreases at higher altitudes, so a longer boiling time will be required. In theory, the time should be increased by 5 minutes for each 300-m (1,000-foot) rise in altitude. For example, at 4000 m (approximately 12,000 feet) above sea level, water boils at 86° C (187° F), so boiling for 60 minutes or longer is required for disinfection. A way to increase the disinfectant effect of boiling is to use “double boiling.” Boil the instruments for 30 to 40 minutes. Let them cool, and then boil for another 30 to 40 minutes.³⁶ This process kills all organisms except for certain bacterial spores.

Alcohols

Alcohols (e.g., methanol, ethanol, and isopropanol) have good activity against bacteria and viruses so long as the equipment first has been cleaned—or, at least, after all the visible surface dirt has been removed from the area to be disinfected. Use 70% or greater concentrations, and have the equipment in contact with the alcohol for 10 minutes or longer; the longer the contact time the better. To prepare a 70% ethanol solution, add 8 parts 90% ethanol to 2 parts water. To prepare a 70% isopropanol solution, add 7 parts standard isopropanol to 3 parts water.⁷¹

Povidone-Iodine

Povidone-iodine (PVD-I; Betadine) may be used for disinfecting instruments. Although exact information about this is sketchy, studies seem to support its use. Use 1 part 10% povidone-iodine solution to 3 parts water for 15 minutes.⁷¹

“Sterile” Dressings

Clean and disinfect cloth for dressings by boiling it in water for 15 minutes or saturating it in alcohol.

Syringes and Needles

It is not possible to clean the interior of disposable syringes and needles well enough to use them safely on another patient. Although syringe reuse is a common practice throughout the world, it is so dangerous that it negates any good that medical treatment produces. Only when no other option exists should cleaning and reusing syringes be considered. If that is the case, the best option is one that the U.S. governmental agencies recommend for needles and syringes potentially contaminated with human immunodeficiency virus. That is, they should be thoroughly cleaned and then immersed in full-strength bleach (5.25% sodium hypochlorite).⁶⁴

Single-Use Needle on Same Patient

With proper precautions, single-use needles can be used multiple times on the same patient. For example, diabetics routinely reuse the same syringe for up to a week. They do this by keeping the needle clean, storing it in a clean container, and ensuring that no one else uses it.

Surgical Instruments

Use alcohol or, if the equipment does not contain plastic or polymers, acetone to chemically sterilize sharp or delicate instruments. Following this soak, rinse them in hot, sterile water and let them dry.⁶⁶ Surgical instruments without a fine tolerance or sharp edges, such as mosquito clamps, towel clips, and large needle holders, may be disinfected in boiling water.⁶⁶ If you do not mind that sharp instruments will lose their edge, metal can be sterilized by holding it over a flame or, even better, by placing the instrument in a pot with a small amount of isopropyl alcohol (enough to create a small pool on the bottom of the pot). Ignite the alcohol, and allow it to burn out, which takes about 5 to 10 minutes. The alcohol burns without leaving significant carbon residue. These techniques may be used when sterilization is really needed or when available resources or time do not allow for disinfection by boiling or soaking in alcohol.⁴⁰

Chin Lift/Jaw Thrust

Elevating the chin is often the easiest method of maintaining an open airway (Figure 23-25). For many patients with diminished consciousness, this is often all that is needed to keep the airway patent. If a cervical spine injury is suspected, the alternative is to push the jaw forward from the mandibular angles.

FIGURE 23-25 Chin lift.

Head Turn

When cervical spine injury is not a concern, turning the patient’s head to one side is a simple but rarely used procedure to open an airway. In patients with significant amounts of redundant tissue in the pharynx and hypopharynx this procedure usually improves airflow.

Positioning the Tongue

If a suspected cervical spine injury prevents head repositioning or the patient’s tongue still blocks the airway after positioning the head, grasp the tongue with gauze and pull it forward. If this opens the airway (it usually does), put a heavy (approximately 2-0) suture vertically through the tip of the tongue in the midline (Figure 23-26), or use a wire fishing line (or similar material), or safety pin (Figure 23-27). This placement avoids significant bleeding. Initially, have someone hold the suture; if needed long-term, pass it through the skin of the lower lip and tie it. Do not use a clamp or forceps that “may in the excitement of the moment be so firmly applied as to nip a piece out of the tongue.”²⁵ Physicians, surgeons, and anesthetists have used these methods since at least the 19th century without complication.⁴⁰

FIGURE 23-26 Suture used to hold the tongue out.

FIGURE 23-27 Safety pin holding the tongue out.

Nasal Airways

One of the most useful pieces of airway equipment, a nasal airway, or “trumpet,” is easy to improvise. Put a safety pin through the end of any soft piece of rubber tubing (e.g., Foley catheter, uncuffed endotracheal tube, radiator hose, solar shower hose, siphon tubing, or inflation hose from a kayak flotation bag or sport pouch) that is the appropriate size for the patient’s nose (Figure 23-28). In adults, the tube’s length beyond the safety pin equals the length from their nares to the meatus of their ears (11 to 13 cm [4.5 to 5 inches]).¹⁰ This “Goldman’s airway” can be made to fit any nose. Consider using nasal airways bilaterally. When placing a nasal airway, lubricate it well, and pass it along the floor of the nose (straight back, not cephalad).⁴⁰

FIGURE 23-28 Goldman’s nasopharyngeal airway.

Surgical Airway (Cricothyrotomy)

Cricothyrotomy—the establishment of an opening in the cricothyroid membrane—is indicated to relieve life-threatening upper airway obstruction when a victim cannot be ventilated effectively from the mouth or nose and endotracheal intubation is not feasible. This may occur in a victim with severe laryngeal edema or with trauma to the face and upper larynx. Cricothyrotomy may also be useful when a person’s upper airway is obstructed by a foreign body that cannot be extracted by abdominal thrusts or direct laryngoscopy.

To perform a cricothyrotomy, cut a hole in the thin cricothyroid membrane and place an endotracheal tube or, in austere circumstances, a suitable hollow object into the trachea to allow ventilation (Box 23-1). Locate the cricothyroid membrane by palpating the victim’s neck, beginning at the top. The first and largest prominence felt is the thyroid cartilage (“Adam’s apple”); the second prominence (below the thyroid cartilage) is the cricoid cartilage. The small space between these two, noted by a depression, is the cricothyroid membrane (Figure 23-30). With the victim lying on his or her back, cleanse the neck around the cricothyroid membrane with an antiseptic if one is readily available. Put on protective gloves. Make a vertical 2.5-cm (1-inch) incision with a knife through the skin over the membrane (go a little bit above and below the membrane) while using the fingers of your other hand to pry the skin edges apart. Anticipate bleeding from the wound. After the skin is incised and spread, puncture the exposed membrane by stabbing it with a knife or other sharp, penetrating object (Figure 23-31, A). Stabilize the larynx between the fingers of one hand and insert the improvised cricothyrotomy tube through the membrane with the other hand (Figure 23-31, B). Secure the object in place with tape.

FIGURE 23-32 Improvised cricothyrotomy tube. A, Cut the plastic drip chamber at its halfway point. B, Insert the spike from the drip chamber through the cricothyroid membrane. C, A bag-valve device will fit over the chamber for ventilation.

FIGURE 23-33 An improvised cricothyroid airway device can be created by cutting the barrel of a syringe at a 45-degree angle at its midway point.

FIGURE 23-30 The cricothyroid membrane is found in the depression between the Adam’s apple (thyroid cartilage) and the cricoid cartilage.

FIGURE 23-31 Cricothyrotomy. A, Locate the cricothyroid membrane and make a vertical 1-inch incision through the skin. B, Insert the pointed end of an improvised cricothyrotomy tube through the membrane.

Complications associated with this procedure include hemorrhage at the insertion site, subcutaneous or mediastinal emphysema resulting from faulty placement of the tube into the subcutaneous tissues rather than into the trachea, and perforation through the posterior wall of the trachea with placement of the tube into the esophagus.