Abstract
Introduction
The interstitial fluid of bone fluid flow is supplied by flowing blood. Blood flow is determined by three kinds of muscles: cardiac, smooth, and skeletal. Cardiac muscle establishes baseline blood pressure. Smooth muscle controls vessel diameter and skeletal muscle creates intermittent intravascular pressure pulses. For the tibia the relevant skeletal muscle is the gastrocnemius which functions as a muscle pump. This study tested the hypotheses: 1) skeletal muscle-caused pressure pulses increase cortical blood flow, 2) extravasation of vascular fluid and, consequently, interstitial bone fluid flow are enhanced by resultant increased microvascular pressure and 3) bone healing is enhanced by increased bone fluid flow.
Methods
Eighteen skeletally mature female New Zealand white rabbits were implanted with bone chamber windows (BCIs) as described previously. The windows were exposed at three weeks and observed weekly until Week 10 using intravital microscopy. During observation, the subject was suspended in prone position in a mesh fabric torso sling jacket so as to eliminate gravity-based reaction forces. Electrodes of a transcutaneous electrical nerve stimulator (TENS) were gel-glued at each rabbits gastroc-soleus position; but activated only in the 11 experimentals. A 4Hz 2.8 ± 1.3V impulse was delivered for 60 minutes. Still and video images were obtained at 0, 2, and 60 minutes following injection of 1μm fluorescent microspheres. Each such injection was followed by injection of 70 kD FITC- or RITC-dextran to define vascularity and capillary filtration. Additional still images were obtained at 5, 30, and 55 minutes. Muscle contraction forces during TENS were obtained acutely following the Week 10 observation with a Futek force transducer cell through an attached nylon suture. Bone mineral density was obtained at Week 3 and Week 10 with a Stratec pQCT and associated software. Data were analyzed statistically using a Wilcoxon signed rank test.
Results
All three hypotheses were supported statistically by the data. The average force produced by TENS stimulated gastrocnemius contraction was 18.98 ± 9.42 N/kg muscle. This produced a microstrain of 192μe in bone around the BCI. Bloodflow results are shown in the figure. On average, flow decreased in controls by 12.6% and increased in experimentals by about 2%. Capillary filtration in experimentals was about 34.6% higher than controls after 60 minutes of TENS. Bone formation rate was 62.5% higher with TENS.
Conclusion
In order to understand the role of fluid flows in bone physiology, we need to know the how and where of movement. These results suggest the part played by skeletal muscle in bone fluid movement cannot be ignored. As with many evolutionary adaptations, the muscle pump's hydrodynamic contribution to bone may be redundant and merely serve as a backup to percolation from poroelastic deformation. On the other hand, it may be crucial in disuse osteoporosis instigating conditions such as microgravity. The measured increases in capillary filtration and blood flow suggest that intravascular pressure which drives the former and resultant percolation has been increased by the muscle pump. It follows that fluid shear on cortical bone cells also increased. The challenge now is to obtain local flow measurements that would tell us how much.