The New Technology of Intramuscular Pressure Recording
The equipment consists of a reusable probe (PiCo; Mammendorfer Institute for Physics and Medicine GmbH, Hattenhofen, Germany) that is sixty centimeters long and a separate, portable, battery-powered (nine-volt-block), handheld device (HANDY; Mammendorfer Institute for Physics and Medicine GmbH) that weighs 200 grams (Fig. 1). Technically, the monitoring system is based on the piezoresistive principle that semiconductors change their electrical resistance as a function of applied pressure. Our system uses a chip with a unicrystalline piezo semiconductor, which is incorporated in a steel case with an outer diameter of either 0.99 or 1.32 millimeters (French size 3 or 4) located at the tip of the probe (Fig. 1). The probe can be sterilized in an autoclave or by gas.
The connection of the probe with the compact device automatically starts the software-controlled self-test and offset; there is no need for keys or knobs on the instrument (Fig. 2). The self-test takes approximately eight seconds and consists of several consecutive steps: (1) activation of the memory, the ports, and the analog-to-digital converter; (2) a check of the display; (3) a check of the battery; and (4) a check of the probe to verify that it is functioning correctly, which is necessary to ensure the quality of the probe after the sterilization procedure. Sensors based on every kind of electronic bridge circuit, especially a Wheatstone-bridge circuit, always have a difference between the pressure zero and the electrical zero. This difference is called zero variation or offset, and it influences the complete pressure measurement. To ensure the accuracy of the measurement, this offset has to be checked. The check of the probe, in turn, consists of several steps: (1) a check of the initial offset value, which should be between clearly defined limits; (2) a control of the drift; and (3) storage of the actual offset, which equates the measured surrounding pressure with zero millimeters of mercury (self-calibration).
After a short audible signal, the system is operational and the liquid-crystal display indicates zero millimeters of mercury. In the case of a failure, a clearly defined error message appears on the display and measurement is not possible. Immediately after the probe is inserted into a compartment, the display indicates the intracompartmental pressure at the point of measurement.
The system is safe in that there are no electrical connections to the patient. It was tested by the National Institute of Trade of Germany and complies with the medical product safety regulations of the European Community with the CE-Mark (93/42/EWG,II,4).
Validation of the Method
The use of the electronic transducer-tipped catheter method was validated in two different experimental settings in which pressure was elevated to known values: a laboratory model involving use of a water column and a model in which pressure was externally applied to the lower limbs of human subjects. Furthermore, intracompartmental pressure was measured in healthy volunteers at rest, after the injection of saline solution, and during exercise.
Laboratory Studies
Under direct vision, eight probes (French size 4) were inserted into a filled water column, with a temperature of 33 degrees Celsius, at different water depths (zero, 13.6, 27.2, 40.8, and 54.4 centimeters, which corresponded to zero, ten, twenty, thirty, and forty millimeters of mercury [zero, 1.33, 2.67, 4.00, and 5.33 kilopascals]). To test the probes at higher pressures, the eight probes were inserted into a calibrated pressure chamber at fifty, eighty, 120, and 160 millimeters of mercury (6.67, 10.66, 16.0, and 21.33 kilopascals).
We had found that the temperature in resting muscle is 33 or 34 degrees Celsius and increases during exercise to as much as 40 or 41 degrees Celsius. We investigated a possible dependence of the measurement system on variations in temperature. First, after calibration at dry room temperature (19, 20, or 21 degrees Celsius), the eight probes were dipped, at depths of zero, ten, twenty, thirty, forty, fifty, eighty, 120, and 160 millimeters of mercury (zero, 1.33, 2.67, 4.00, 5.33, 6.67, 10.66, 16.00, and 21.33 kilopascals), for ten minutes in the water column with a temperature of 33 degrees Celsius. Second, after calibration at dry room temperature, the probes were dipped, at the same depths, for ten minutes in the water column with a temperature of 40 degrees Celsius. Then, to assess whether the measurement drift was affected by a possible difference between calibration in water and a dry calibration, the probes were calibrated at 20 degrees Celsius in water and then dipped into the water column with a temperature of 40 degrees Celsius. To test stability as a function of time, the eight probes were tested in the range of zero to forty millimeters of mercury (zero to 5.33 kilopascals) for zero to twenty-four hours (zero, 0.5, 1.0, 3.0, 6.0, 12.0, and 24.0 hours) in the water column at 33 degrees Celsius.
Clinical Studies of Pressure in the Tibialis Anterior Muscle
Healthy Volunteers
Normal pressure at rest: Normal resting values for pressure in the tibialis anterior muscle were determined for twenty male volunteers (age range, twenty to thirty-nine years) who were in a supine, relaxed position. After preparation of a sterile field, the skin and the subcutaneous tissue were anesthetized with an injection of one milliliter of 1 percent Xylocaine (lidocaine) placed 1.5 centimeters lateral to the anterior ridge of the tibia. Without a skin incision, a 14-gauge (2.1-millimeter) intravenous cannula then was introduced into the anterior compartment of the leg. The fascia was penetrated at an angle of approximately 45 degrees in a distal direction (Fig. 2). The trocar was then removed, and the French-size-4 probe was connected to the handheld device. After the self-test of the measurement system, the probe was inserted through the cannula and bluntly introduced two centimeters beyond the tip of the cannula parallel to the muscle fibers between the overlying fascia and the centrally located intramuscular tendon at a depth of approximately 1.5 centimeters from the fascia. The cannula was then removed.
Externally applied pressure: In four healthy volunteers, which included the three of us, the probe was inserted into the anterior compartment of the left leg as already described. External pressure was superimposed on the internal pressure with use of antishock trousers (LSP 600; Life Support Products, St. Louis, Missouri). With use of the calibrated manometer of the antishock trousers, a known pneumatic pressure was uniformly applied over the lower extremity. The external pressure was increased in twenty-millimeter (2.67-kilopascal) increments from zero to 100 millimeters of mercury (zero to 13.33 kilopascals) for ten minutes at each pressure. Linear regression analysis was performed to evaluate the relationship between these externally applied pressures and the measured intracompartmental pressures.
Injection of fluid into the muscle: To study the responsiveness of the pressure-monitoring method, two probes (P1 and P2) were inserted into the middle third of the tibialis anterior muscle of one of us. The probes were placed five centimeters apart and 1.5 centimeters lateral to the anterior ridge of the tibia. In the first step, ten milliliters of sterile saline solution was injected three times at a site 2.5 centimeters distal to the distally inserted probe (P1) and 7.5 centimeters distal to the proximally inserted probe (P2). In the second step, ten milliliters of saline solution was injected twice between the two transducer-tipped catheters (2.5 centimeters from P1 and 2.5 centimeters from P2). The measured pressures were recorded continuously at a frequency of one hertz.
High-frequency recording during exercise: To evaluate the ability of the catheter to record intramuscular pressure during exercise, three electronic transducer-tipped catheters were inserted into the tibialis anterior muscle of one of us to a depth of 1.5 centimeters. The catheters were placed five centimeters apart and were connected to a measurement system that included a three-channel analog-to-digital converter and a personal computer. The probes were fixed to the skin to prevent dislocation during the exercise, and they were calibrated. The pressure course was measured with use of a software program (ARGUS; Mammendorfer Institute for Physics and Medicine GmbH) that was developed to analyze pressure measurements in patients who have suspected exertional compartment syndrome; it permitted data-recording at a frequency that ranged from one to 200 hertz. The volunteer then performed four ten-minute exercises on a treadmill: walking at six kilometers per hour on a level surface, walking at six kilometers per hour on a gradient of 10 percent, walking at eight kilometers per hour on a gradient of 10 percent, and running at ten kilometers per hour on a gradient of 10 percent. A recording frequency of ten hertz was chosen for the experiment.
Patients with Suspected Compartment Syndrome
From March 1994 to December 1996, intramuscular pressure in the tibialis anterior muscle was recorded prospectively in twenty-five patients who had suspected compartment syndrome. When a patient was unconscious, the cannula was introduced without any anesthesia. We included patients who had painful, swollen limbs and palpably tense compartments. No patient had a motor or sensory deficit.
Sixteen patients had a tibial fracture. The eleven men and five women had a mean age of thirty-seven years (range, nineteen to sixty-seven years). For four of these patients, the intramuscular pressure was monitored for six to twenty hours after admission. Seven patients, who were included because of soft-tissue injury with tense compartments, were artificially ventilated and unconscious. Measurement was performed in the emergency room or the operating room.
In two men (twenty and thirty-two years old) who had severe soft-tissue injury, the intramuscular pressure was recorded during intramedullary nailing of the tibia without reaming and at every half hour for the next twelve and eight hours, respectively.
Six patients (two men and four women), with a mean age of fifty-three years (range, forty-two to sixty-eight years), had an elective corrective osteotomy of the proximal part of the tibia. The intramuscular pressure was recorded during the operation and at every half hour for the next seventeen to twenty-one hours.
In addition, one patient had an acute exertional compartment syndrome of the tibialis anterior muscle. The intramuscular pressure was measured before the performance of a fasciotomy. The correct diagnosis had been delayed because the pain was misinterpreted as resulting from acute muscular tetanic spasm induced by hyperventilation. Therefore, the fasciotomy was performed eighteen hours after the development of the acute exertional compartment syndrome.
Informed Consent
Written informed consent was obtained from all volunteers and conscious patients who did not need emergency management. Measurement of intracompartmental pressure was considered to be an essential part of the management of the twenty-five conscious and unconscious patients who were suspected of having an acute compartment syndrome. The study was approved by our local Institutional Review Board.
Statistical Analysis
The Kruskal-Wallis test was used to analyze the differences in the pressure in the experimental investigations of temperature-induced drift and the stability of the measurements as a function of time. Values are given as the mean and standard deviation. A p value of less than 0.05 was considered to be significant.
Our findings show that the electronic transducer-tipped catheter system accurately measures intramuscular pressure. The new catheter is small, with a diameter of 0.99 or 1.32 millimeters (French size 3 or 4); is minimally traumatic; and is easy to use. The responsiveness of the pressure-measuring system is extremely high, and no equilibration time is necessary to provide accurate results. Because of the ease of use and the uncomplicated technique for insertion, the method is highly suitable for clinical monitoring of tissue pressure in injured extremities.
Our laboratory studies demonstrated that the general range of accuracy with this method, in the tested range of pressures between zero and 160 millimeters of mercury (zero and 21.33 kilopascals), is approximately one millimeter of mercury (0.13 kilopascal). The internal software of this handheld device allows an automatic compensation of the measured values between 20 and 40 degrees Celsius, resulting in good thermal stability and a clinically unimportant drift of 1.25 millimeters of mercury (0.17 kilopascal) at most. Furthermore, the drift from 20 to 40 degrees Celsius was less marked if calibration was performed in warm water (20 degrees Celsius) rather than at dry room temperature. At the temperature of the resting muscle (33 degrees Celsius), the measurement was shown to be highly stable, with no relevant drift during long-term measurements. Generally, the extremely small drift that was observed corresponded to the physical characteristics of the semiconductor piezoelectric crystal.
In the tibialis anterior muscle of twenty normal limbs, the resting pressure was a mean (and standard deviation) of 13.1 ± 8.3 millimeters of mercury (1.75 ± 1.11 kilopascals). This finding is consistent with those of Matsen et al.11 (mean, 11.5 ± 0.5 millimeters of mercury [1.53 ± 0.07 kilopascals]), Reneman18 (range, 7.0 to 16.0 millimeters of mercury [0.93 to 2.13 kilopascals]), Logan et al.9 (mean, 13.2 ± 6.7 millimeters of mercury [1.76 ± 0.89 kilopascals]), Rorabeck et al.20 (mean, 10.9 ± 1.1 millimeters of mercury [1.45 ± 0.15 kilopascals]), and Nkele et al.17 (range, -2 to 17.5 millimeters of mercury [-0.27 to 2.33 kilopascals]), all of whom used infusion techniques that recorded the total tissue pressure. Other investigators have reported lower pressures with use of the wick method, which measures only the fluid pressure in the tissue1,6,12,14,22. In contrast with these studies, in which values between zero and 10.0 millimeters of mercury (zero and 1.33 kilopascals) were observed, the findings in our study showed a tendency toward a higher resting pressure in the tibialis anterior muscle. Although the recorded pressures depend on the method that is used, one possible explanation for this observed tendency is that the new catheter measures the total tissue pressure as the sum of the fluid and solid components. According to Guyton et al.5, the diagnosis of acute compartment syndrome in an injured extremity must be based on the total tissue pressure because both the solid and the fluid components act on the local vasculature. A potential source of error associated with use of the new electronic system is placement of the needle into the intramuscular tendon, which gives a falsely high reading16,22,26. A falsely high reading theoretically can also be obtained if crosswise-tensed muscle fibers press on the sensing area of the probe22,26. Therefore, the probe should be inserted parallel to the muscle fibers22,26.
The responsiveness of the electronic transducer-tipped catheter was observed during the injection of saline solution and during the application of an external pressure. The high sensitivity of the measurement technique allowed an immediate reaction to artificial elevations of intramuscular pressure and demonstration of the subsequently slow decrease of intramuscular pressure that was due to fluid convection down a pressure gradient within the muscle. Several investigators have shown that tissue pressure is linearly dependent on the resting or internal pressure of the tissue and the superimposed, or external, pressure11,12. An excellent correlation was observed between the pressures applied externally by the antishock trousers and the measured intramuscular pressures (r = 0.997 to 0.999), indicating the validity of the measurement of pressure in human muscle with use of the electronic transducer-tipped catheter. The total pressure was almost exactly the sum of the externally applied pressure and the baseline resting pressure (Fig. 3).
The catheter did not lose its accuracy as long as twenty-one hours after corrective osteotomy or intramedullary nailing of tibial fractures. In our experience, no clotting was observed when the probes were placed directly into a hematoma or into tissues with large collections of blood. Unlike the currently used fluid-filled systems, such as the wick, slit, and solid-state transducer intracompartmental catheter3,6,7,10,19,20, the new catheter could measure the pressure course continuously over the long term without any additional manipulation. The major problem with fluid-filled catheters is that they can become blocked by a blood clot during long-term monitoring7,13. Although the fibers at the orifice of the wick catheter prevent occlusion caused by impingement of the surrounding soft tissue and thus maintain channels for interstitial fluid, coagulation around the tip is possible. Therefore, the wick catheter can record pressure for only as long as eight hours7. Compared with the wick catheter, the slit catheter, described in 1981 by Rorabeck et al.19, allows a more sensitive response to changes in fluid pressure in tissue and is usable for a longer time because of the more open design of the tip of the probe. Nevertheless, the slit catheter requires as many as three, four, or five flushes with saline solution to maintain patency throughout several hours of recording3. In contrast to other catheter systems, our new probe can provide accurate recording for as long as twenty-four hours. In our clinical experience (not reported in this study), accurate recording was observed for as long as several days.
The piezoresistive technique allows measurement without additional handling or additional disposable items. It is not necessary to inject saline solution, which creates an artificially high pressure around the orifice at the tip14,15. Compared with the needle technique of Whitesides et al.27, described in 1975, the new technique avoids bubbles of air in the catheter. Although the needle technique is uncomplicated, it is considered the least accurate of those available because it produces falsely high values when low pressures are measured and falsely low values when high pressures are measured3,11,13,20,25.
The absence of hydrostatic artifacts caused by movement of the tip of the catheter or of the limb is an additional characteristic of the electronic transducer-tipped catheter system that makes it preferable for long-term measurement of intramuscular pressure in a patient at rest. As described in 1990 by Crenshaw et al.4, a change in the position of the transducer or the limb can induce measurement artifacts of as much as forty millimeters of mercury (5.33 kilopascals). Therefore, in contrast to the needle technique of Whitesides et al.27 and to the wick and slit-catheter techniques, it is not necessary to calibrate hydrostatic fluid pressure continuously or to hold the fluid's meniscus stationary in a capillary tube by adjusting its hydrostatic height above the catheter when the patient is moved6,14,21,29. Our study demonstrated that even when the catheter was raised or lowered from the reference point during extreme muscular activity there were no hydrostatic pressure artifacts. Similar to our new catheter, the transducer-tipped fiber-optic catheter described by Crenshaw et al.4 was not affected by changes in the position of the patient because of the independence of the system from hydrostatic pressure. However, although it measures intramuscular pressure without fluid artifacts, the fiber-optic transducer is relatively large and must be attached to an intracath sheath (outer diameter, 2.1 millimeters) filled with saline solution. This large sheath causes trauma to the tissue and is uncomfortable for the patient, especially during studies of muscular activity. In addition, a ten-minute equilibration period after insertion should be allowed before a reading of the tissue pressure is obtained. Another problem is the possible breakage of the optical fibers caused by strenuous exercise. Therefore, this procedure is not commonly used in clinical applications
In our experience, movement of the limbs produced no dislocation or breakage of the inserted electronic transducer-tipped catheter probes and no electronic artifacts. The catheter could record data during strong muscular activity with a high temporal resolution of one to 200 hertz and with a very dynamic response to exercise; thus, computer-assisted instantaneous recording of the pressure course during the gait cycle is possible. In our study, the intramuscular pressure during muscular activity increased to as much as 180 millimeters of mercury (24.00 kilopascals) in a healthy volunteer. This finding is consistent with the range of recorded pressures of 100 to 250 millimeters of mercury (13.33 to 33.33 kilopascals) that has been observed by other authors2,22,23. Although the Myopress catheter technique, which was described by Styf and Körner22 in 1986, is simple and responsive, there are problems with regard to hydrostatic artifacts caused by the saline-solution-filled catheter line that connects a subject to the pressure transducer during exercise7. The other currently used catheters, such as the wick and slit catheters, are not suitable for high-fidelity dynamic studies of subjects during exercise and gait analyses because of low-frequency response, hydrostatic pressure artifacts, and occlusion of the catheter tip7,25,26. For this reason, slit catheters must be flushed repeatedly26. Another electronic transducer-tipped catheter, the small Millar catheter, also provides good dynamic response to changes in intramuscular pressure7,26. Both the Millar catheter and the catheter described in the present study incorporate the current technology for measurement and provide artifact-free, excellent dynamic response to changes in intramuscular pressure.
In summary, acute compartment syndrome must be diagnosed early in order to prevent severe neuromuscular deficits. To meet this objective, the results of the clinical examination must be evaluated in relation to measurements of compartment pressure. The electronic instrument described in the present report is suitable for accurate and valid measurements, as it prevents hydrostatic pressure artifacts and obviates the need for infusion of fluids. The system also provides long-term monitoring without the need for additional manipulation either intraoperatively or during nonoperative management of patients in the hospital. The connection of the probe with the monitoring system automatically initiates the software-controlled self-calibration procedure, which allows immediate use. The electronic transducer-tipped catheter can be resterilized and reused. The catheter, which causes little trauma, offers dynamic responses and provides high-frequency recordings of intramuscular pressure during exercise. It can be recommended for routine use in the diagnosis of acute and exertional compartment syndromes.
NOTE: The authors thank Doren Carabeo for his ongoing advice and support in the preparation of this manuscript.