Room G, 10/16/2000 9: 00 AM - 11: 00 AM (PS) Effects of Lithotomy Position and External Compression on Lower Leg Muscle Compartment Pressure

Purpose: Hemodilution and inflammation lead to edema and increased muscle compartment pressure after cardiac surgery. The aim of this study was to find whether muscle compartment pressure was affected by the addition of albumin and mannitol to the pump prime, heparin coating or leukocyte depletion. Additionally, we studied the relationship between intraocular pressure and lower leg muscle compartment pressure. Edema during and following cardiac surgery is due to hemodynamic, osmotic and inflammatory changes, according to Starling’s Law. We attempted to influence the osmotic balance and reduce the inflammatory response in order to reduce the edema. Methods: Thirty-six patients who underwent cardiac surgery were randomly allocated into four groups. Group A received albumin and mannitol into the pump prime. Group B had an, heparin-coated perfusion system, Group C had a leukocyte-depletion arterial line filter and Group D was the control group, where intraocular pressure was also measured. Results: Lower leg muscle compartment pressure increased significantly during and after cardiac surgery in all groups, but this increase was significantly less in Group A than in the control group 24 h after surgery. No correlation was found between muscular compartment pressure and intraocular pressure. The intraocular pressure profile is different from the muscular compartment pressure and recovers much faster. Conclusion: Lower leg muscle compartment pressure and intraocular pressure behave differently during and after cardiac surgery. Albumin and mannitol added to the pump prime decreases muscle compartment pressure after cardiac surgery.

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Effects of Lithotomy Position and External Compression on Lower Leg Muscle Compartment Pressure

Anesthesiology ◽

10.1097/00000542-200109000-00014 ◽

2001 ◽

Vol 95 (3) ◽

pp. 632-636 ◽

Cited By ~ 49

Author(s):

Susanne D. Pfeffer ◽

John R. Halliwill ◽

Mark A. Warner

Keyword(s):

Supine Position ◽

Case Reports ◽

Tibialis Anterior Muscle ◽

Applied Pressure ◽

Lower Leg ◽

Lithotomy Position ◽

External Compression ◽

Extended Surgery ◽

Intermittent Compression ◽

Muscle Compartment

Background Case reports have suggested that externally applied pressure from antithrombosis devices may contribute to the development of compartment syndromes during extended surgery in the lithotomy position. The purpose of this study was to assess the effects of a pneumatic compression device on directly measured intracompartment pressure in the lower leg with the leg positioned in the lithotomy position. Methods In 25 conscious, healthy men and women, the authors measured pressure within the tibialis anterior muscle compartment with the leg supine and in the lithotomy position with and without intermittent compression. Three different devices were used to keep the leg in the lithotomy position, supporting the leg either behind the knee, under the calf, or at the ankle. Results The lithotomy position with support behind the calf or knee increased intracompartment pressure to 16.5+/-3.4 versus 10.7+/-5.8 mmHg supine (mean +/- SD; P < 0.05). The addition of intermittent compression decreased pressure to 13.4+/-5.1 mmHg during lithotomy (P < 0.05) and to 9.1+/-7.0 mmHg in the supine position (P < 0.05). In contrast, the lithotomy position with support near the ankle decreased intracompartment pressure to 8.7+/-5.6 versus 13.3+/-5.1 mmHg supine (P < 0.05). The addition of intermittent compression decreased pressure to 6.5+/-5.4 mmHg during lithotomy (P < 0.05) and to 10.3+/-4.7 mmHg in the supine position (P < 0.05). Conclusions These results show that the lithotomy position is associated with changes in intracompartment pressure that are dependent on the method of leg support used. Furthermore, they indicate that intermittent external compression can reduce intracompartment pressure in the lower leg. Therefore, increases in intracompartment pressure during surgery in the lithotomy position with the calf or knee supported may be one of the factors that contribute to the development of compartment syndrome. Further, use of intermittent external compression may significantly reduce this pressure increase.

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Role of Repeat Muscle Compartment Pressure Measurements in Chronic Exertional Compartment Syndrome of the Lower Leg

Orthopaedic Journal of Sports Medicine ◽

10.1177/2325967117711121 ◽

2017 ◽

Vol 5 (6) ◽

pp. 232596711771112 ◽

Cited By ~ 4

Author(s):

Aniek P. M. van Zantvoort ◽

Johan A. de Bruijn ◽

Michiel B. Winkes ◽

Adwin R. Hoogeveen ◽

Joep A. W. Teijink ◽

...

Keyword(s):

Compartment Syndrome ◽

Lower Leg ◽

Pressure Measurements ◽

Compartment Pressure ◽

Chronic Exertional Compartment Syndrome ◽

Exertional Compartment Syndrome ◽

Muscle Compartment

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Numerical steady flow solutions of the lower leg venous circulation: effects of external compression

The European Physical Journal Applied Physics ◽

10.1051/epjap:2007066 ◽

2007 ◽

Vol 38 (3) ◽

pp. 287-297

Author(s):

J.-M. Fullana ◽

P. Flaud

Keyword(s):

Steady Flow ◽

Lower Leg ◽

External Compression ◽

Venous Circulation

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Lower leg muscle structure and function are altered in long-distance runners with medial tibial stress syndrome: a case control study

Journal of Foot and Ankle Research ◽

10.1186/s13047-021-00485-5 ◽

2021 ◽

Vol 14 (1) ◽

Author(s):

Joshua Mattock ◽

Julie R. Steele ◽

Karen J. Mickle

Keyword(s):

Lower Leg ◽

Structure And Function ◽

Flexor Hallucis Longus ◽

Plantar Flexor ◽

Distance Runners ◽

Long Distance ◽

Cross Sectional ◽

Muscle Structure ◽

Leg Muscle ◽

And Function

Abstract Background Medial tibial stress syndrome (MTSS) is a common lower leg injury experienced by runners. Although numerous risk factors are reported in the literature, many are non-modifiable and management of the injury remains difficult. Lower leg muscle structure and function are modifiable characteristics that influence tibial loading during foot-ground contact. Therefore, this study aimed to determine whether long-distance runners with MTSS displayed differences in in vivo lower leg muscle structure and function than matched asymptomatic runners. Methods Lower leg structure was assessed using ultrasound and a measure of lower leg circumference to quantify muscle cross-sectional area, thickness and lean lower leg girth. Lower leg function was assessed using a hand-held dynamometer to quantify maximal voluntary isometric contraction strength and a single leg heel raise protocol was used to measure ankle plantar flexor endurance. Outcome variables were compared between the limbs of long-distance runners suffering MTSS (n = 20) and matched asymptomatic controls (n = 20). Means, standard deviations, 95 % confidence intervals, mean differences and Cohen’s d values were calculated for each variable for the MTSS symptomatic and control limbs. Results MTSS symptomatic limbs displayed a significantly smaller flexor hallucis longus cross-sectional area, a smaller soleus thickness but a larger lateral gastrocnemius thickness than the control limbs. However, there was no statistical difference in lean lower leg girth. Compared to the matched control limbs, MTSS symptomatic limbs displayed deficits in maximal voluntary isometric contraction strength of the flexor hallucis longus, soleus, tibialis anterior and peroneal muscles, and reduced ankle plantar flexor endurance capacity. Conclusions Differences in lower leg muscle structure and function likely render MTSS symptomatic individuals less able to withstand the negative tibial bending moment generated during midstance, potentially contributing to the development of MTSS. The clinical implications of these findings suggest that rehabilitation protocols for MTSS symptomatic individuals should aim to improve strength of the flexor hallucis longus, soleus, tibialis anterior and peroneal muscles along with ankle plantar flexor endurance. However, the cross-sectional study design prevents us determining whether between group differences were a cause or effect of MTSS. Therefore, future prospective studies are required to substantiate the study findings.

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Spatio-Temporal Separation of Roll and Pitch Balance-Correcting Commands in Humans

Journal of Neurophysiology ◽

10.1152/jn.00538.2004 ◽

2005 ◽

Vol 94 (5) ◽

pp. 3143-3158 ◽

Cited By ~ 27

Author(s):

C. Grüneberg ◽

J. Duysens ◽

F. Honegger ◽

J.H.J. Allum

Keyword(s):

Muscle Activity ◽

Lower Leg ◽

Trunk Muscles ◽

Roll Motion ◽

Stretch Reflexes ◽

Ankle Muscles ◽

Roll Velocity ◽

Main Action ◽

Leg Muscle ◽

Balance Corrections

This study was designed to provide evidence for the hypothesis that human balance corrections in response to pitch perturbations are controlled by muscle action mainly about the ankle and knee joints, whereas balance corrections for roll perturbations are controlled predominantly by motion about the hip and lumbro-sacral joints. A dual-axis rotating support surface delivered unexpected random perturbations to the stance of 19 healthy young adults through eight different directions in the pitch and the roll planes and three delays between pitch and roll directions. Roll delays with respect to pitch were no delay, a short 50-ms delay of roll with respect to pitch movements, (chosen to correspond to the onset time of leg muscle stretch reflexes), and a long 150-ms delay between roll and pitch movements (chosen to shift the time when trunk roll velocity peaks to the time when trunk peak pitch velocity normally occurs). Delays of stimulus roll with respect to pitch resulted in delayed roll responses of the legs, trunk, arms, and head consistent with stimulus delay without any changes in roll velocity amplitude. Delayed roll perturbations induced only small changes in the pitch motion of the legs and trunk; however, major changes were seen in the time when roll motion of the trunk was arrested. Amplitudes and directional sensitivity of short-latency (SL) stretch reflexes in ankle muscles were not altered with increasing roll delay. Small changes to balance correcting responses in ankle muscles were observed. SL stretch reflexes in hip and trunk muscles were delayed, and balance-correcting responses in trunk muscles became split into two distinct responses with delayed roll. The first of these responses was small and had a directional responsiveness aligned more along the pitch plane. The main, larger, response occurred with an onset and time-to-peak consistent with the delay in trunk roll displacement and its directional responsiveness was roll oriented. The sum of the amplitudes of these two types of balance-correcting responses remained constant with roll delay. These results support the hypothesis that corrections of the body's pitch and roll motion are programmed separately by neural command signals and provide insights into possible triggering mechanisms. The evidence that lower leg muscle balance-correcting activity is hardly changed by delayed trunk roll also indicates that lower leg muscle activity is not predominant in correcting roll motion of the body. Lower leg and trunk muscle activity appears to have a dual action in balance corrections. In trunk muscles the main action is to correct for roll perturbations and the lesser action may be an anticipatory stabilizing reaction for pitch perturbations. Likewise, the small changes in lower leg muscle activity may result from a generalized stabilizing reaction to roll perturbations, but the main action is to correct for pitch perturbations.

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Scaling of maximal oxygen uptake by lower leg muscle volume in boys and men

Journal of Applied Physiology ◽

10.1152/japplphysiol.01213.2005 ◽

2006 ◽

Vol 100 (6) ◽

pp. 1851-1856 ◽

Cited By ~ 35

Author(s):

Keith Tolfrey ◽

Alan Barker ◽

Jeanette M. Thom ◽

Christopher I. Morse ◽

Marco V. Narici ◽

...

Keyword(s):

Body Size ◽

Confidence Interval ◽

Oxygen Uptake ◽

Maximal Oxygen Uptake ◽

Lower Leg ◽

Muscle Volume ◽

Fat Free Mass ◽

Percentage Body Fat ◽

Leg Muscle

The aim of this study was to critically examine the influence of body size on maximal oxygen uptake (V̇o2 max) in boys and men using body mass (BM), estimated fat-free mass (FFM), and estimated lower leg muscle volume (Vol) as the separate scaling variables. V̇o2 max and an in vivo measurement of Vol were assessed in 15 boys and 14 men. The FFM was estimated after percentage body fat had been predicted from population-specific skinfold measurements. By using nonlinear allometric modeling, common body size exponents for BM, FFM, and Vol were calculated. The point estimates for the size exponent (95% confidence interval) from the separate allometric models were: BM 0.79 (0.53–1.06), FFM 1.00 (0.78–1.22), and Vol 0.64 (0.40–0.88). For the boys, substantial residual size correlations were observed for V̇o2 max/BM0.79 and V̇o2 max/FFM1.00, indicating that these variables did not correctly partition out the influence of body size. In contrast, scaling by Vol0.64 led to no residual size correlation in boys or men. Scaling by BM is confounded by heterogeneity of body composition and potentially substantial differences in the mass exponent between boys and men. The FFM is precluded as an index of involved musculature because Vol did not represent a constant proportion of FFM [Vol∝FFM1.45 (95% confidence interval, 1.13–1.77)] in the boys (unlike the men). We conclude that Vol, as an indicator of the involved muscle mass, is the most valid allometric denominator for the scaling of V̇o2 max in a sample of boys and men heterogeneous for body size and composition.

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