Summary
The efficacy of a modified fibre optic transducer-tipped catheter system for measuring intramuscular pressures during exercise was determined. A microcapillary infusion technique using a catheter was employed as the standard of comparison due to its established dynamic properties. Pressures were measured in the tibialis anterior muscle of six healthy adults at rest before exercise, during isometric and concentric exercise, and at rest after exercise. The fibre optic system measured contraction pressures equal to the microcapillary infusion technique during all phases of the exercise protocols but recorded a lower relaxation pressure during isometric exercise and a lower rest pressure following 20 min of concentric exercise. Negative relaxation pressures were recorded by the fibre optic system for two subjects during continuous concentric exercise. It is hypothesized that a piston effect, due to the sliding of muscle fibres at the catheter tip following a contraction, rendered falsely low pressures during relaxation and that this artefact was reflected in the subsequent rest pressure following exercise. The larger volume (157 mm3) and area (3.49 mm2) of the fibre optic catheter in the muscle made it more prone to this effect than the conventional catheter (39 mm3 and 0.87 mm2, respectively). The fibre optic system may be preferred when recording the musclecontraction pressures during complex limb movements but should not be used when assessing the relaxation pressures or the pressure at rest following exercise.
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References
Aukland K, Nicolaysen G (1981) Interstitial fluid volume: local regulatory mechanisms. Physiol Rev 61:556–583
Crenshaw AG, Styf JR, Hargens AR, Mubarak SJ (1990) A new “transducer-tipped” fiber optic catheter for measuring intramuscular pressures. J Orthop Res 8:464–468
Hargens AR, Mubarak SJ (1981) Laboratory diagnosis of acute compartment syndrome. In: Mubarak SJ, Hargens AR (eds) Compartment Syndromes and Volkmans Contracture. Saunders, Philadelphia, pp 106–122
Jacobsson S, Kjellmer I (1964) Accumulation of fluid in exercising skeletal muscle. Acta Physiol Scand 60:286–292
Järvholm U, Palmerud G, Styf J, Herberts P, Kadefors R (1988) Intramuscular pressure in the supraspinatus muscle. J Orthop Res 6:230–238
Järvholm U, Palmerud G, Herberts P, Högfors C, Kadefors R (1989) Intramuscular pressure and electromyography in the supraspinatus muscle at shoulder abduction. Clin Orthop 245:102–109
Körner L, Parker P, Almström C, Andersson GBJ, Herberts P, Kadefors R, Palmerud G, Zetterberg C (1984) Relation of intramuscular pressure to the force output and myoelectric signal of skeletal muscle. J Orthop Res 2:289–296
Lundvall J, Mellander S, Westling H, White T (1972) Fluid transfer between blood and tissues during exercise. Acta Physiol Scand 85:258–269
Matsen FA, Mayo KA, Sheridan GW, Krugmire RB (1976) Monitoring of intramuscular pressure. Surgery 79:702–709
McDermott AGP, Marble AE, Yabsley RH, Phillips MB (1982) Monitoring dynamic anterior compartment pressures during exercise. A new technique using the STIC catheter. Am J Sports Med 10:83–89
Mubarak SJ (1981) Exertional compartment syndromes. In: Mubarak SJ, Hargens AR (eds) Compartment syndromes and Volkmans contracture. Saunders, Philadelphia, pp 209–226
Reneman RS (1975) The anterior and the lateral compartmental syndrome of the leg due to intensive use of muscles. Clin Orthop 113:69–80
Rorabeck CH (1986) Exertional tibialis posterior compartment syndrome. Clin Orthop 208:61–64
Rorabeck CH, Castle GSP, Hardie R, Logan J (1981) Compartmental pressure measurements: an experimental investigation using the Slit catheter. J Trauma 21:446–449
Rorabeck CH, Bourne RB, Fowler PJ, Finlay JB, Nott L (1988) The role of tissue pressure measurement in diagnosing chronic anterior compartment syndrome. Am J Sports Med 16:143–146
Sejersted OM, Hargens AR, Kardell KR, Blom P, Jensen O, Hermansen L (1984) Intramuscular fluid pressure during isometric contraction of human skeletal muscle. J Appl Physiol 56:287–295
Sjögaard G, Adams RP, Saltin B (1985) Water and ion shifts in skeletal muscle of human with intense dynamic knee-extension. Am J Physiol 248:R190-Rl96
Sjögaard G, Kiens B, Jorgensen K, Saltin B (1986) Intramuscular pressure, EMG and blood flow during low-level prolonged static contraction in man. Acta Physiol Scand 128:475–484
Styf JR (1989) Chronic exercise-induced pain in the anterior aspect of the lower leg. An overview of diagnosis. Sports Med 7:331–339
Styf JR, Körner LM (1986) Microcapillary infusion technique for measurement of intramuscular pressure during exercise. Clin Orthop 207:253–262
Styf JR, Körner LM (1987) Diagnosis of chronic anterior compartment syndrome in the lower leg. Acta Orthop Scand 58:139–144
Styf JR, Crenshaw AG, Hargens AR (1989) Intramuscular pressures during exercise-comparison of measurements with and without infusion. Acta Orthop Scand 60:593–596
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This project was performed at the Division of Orthopaedics and Rehabilitation, Veterans Administration Medical Center and the University of California San Diego
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Crenshaw, A.G., Styf, J.R. & Hargens, A.R. Intramuscular pressures during exercise: an evaluation of a fiber optic transducer-tipped catheter system. Europ. J. Appl. Physiol. 65, 178–182 (1992). https://doi.org/10.1007/BF00705077
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DOI: https://doi.org/10.1007/BF00705077