Effects of the Ankle Flexion Angle During Anterior Talofibular Ligament Reconstruction on Ankle Kinematics, Laxity, and In Situ Forces of the Reconstructed Graft

Background: This study aimed to evaluate the effects of the ankle flexion angle during anterior talofibular ligament (ATFL) reconstruction on ankle kinematics, laxity, and in situ force of a graft. Methods: Twelve cadaveric ankles were evaluated using a 6–degrees of freedom robotic system to apply passive plantar flexion and dorsiflexion motions and multidirectional loads. A repeated measures experiment was designed using the intact ATFL, transected ATFL, and reconstructed ATFL. During ATFL reconstruction (ATFLR), the graft was fixed at a neutral position (ATFLR 0 degrees), 15 degrees of plantar flexion (ATFLR PF15 degrees), and 30 degrees of plantar flexion (ATFLR PF30 degrees) with a constant initial tension of 10 N. The 3-dimensional path and reconstructed graft tension were simultaneously recorded, and the in situ force of the ATFL and reconstructed grafts were calculated using the principle of superposition. Results: The in situ forces of the reconstructed grafts in ATFLR 0 degrees and ATFLR PF 15 degrees were significantly higher than those of intact ankles. The ankle kinematics and laxity produced by ATFLR PF 30 degrees were not significantly different from those of intact ankles. The in situ force on the ATFL was 19.0 N at 30 degrees of plantar flexion. In situ forces of 41.0, 33.7, and 21.9 N were observed at 30 degrees of plantar flexion in ATFLR 0, 15, and 30 degrees, respectively. Conclusion: ATFL reconstruction with the peroneus longus (PL) tendon was performed with the graft at 30 degrees of plantar flexion resulted in ankle kinematics, laxity, and in situ forces similar to those of intact ankles. ATFL reconstructions performed with the graft fixed at 0 and 15 degrees of the plantar flexion resulted in higher in situ forces on the reconstructed graft. Clinical Relevance: Fixing the ATFL tendon graft at 30 degrees of plantar flexion results in an in situ force closest to that of an intact ankle and avoids the excessive tension on the reconstructed graft.

Treatment of postoperative wounds using pectin-based reinforced dressings and their antimicrobial activity

A reinforced pectin-based dressing with a reinforcing element containing the antimicrobial agent chlorhexidine bigluconate has been developed. In vitro studies have shown that the hydrogel pectin dressing containing 0.03 ÷ 1.5 % chlorhexidine bigluconate inhibits the growth of both gram-positive (S. aureus) and gram-negative (P. aeruginosa) bacteria. The dressing can be used in the complex treatment of postoperative wounds with infectious-inflammatory process. The efficacy of different doses of chlorhexidine bigluconate was characterized by growth inhibition and increase of microorganism-free areas on the culture medium around the site of dressing localization, and regardless of the type of bacteria. Bacterial growth inhibition radius size depends on the dose of chlorhexidine in the hydrogel pectin dressing. The inhibition of growth of S. aureus and P. aeruginosa is directly proportional to chlorhexidine bigluconate content. The increase of dressing saturation with chlorhexidine to 1.0 and 1.5 % recorded the maximum inhibition of the growth of microorganisms. A veterinary clinical trial has shown a good therapeutic effect in the wound healing, in particular in the complex treatment of postoperative and accidental wounds both in the presence of infectious-inflammatory process and in its absence. The reinforced pectin-based dressing with cotton (or polypropylene) reinforcement element containing chlorhexidine bigluconate reduces the cost of dressings and bandaging frequency during wound healing. It protects the wound surface from contamination, mechanical irritation, bacterial contamination and the development of secondary infection. The dressing promotes good water, air and heat exchange between the wound and the environment, adsorbs excess exudate, maintains a moist environment and does not cause hyperosmotic damage and drying of the wound. Surgical wound healing occurred under the initial tension for 7 days. Considering the method of its application, this dressing is suitable for use on different parts of the animal's body (neck, withers, chest and abdomen, lower back, buttocks, thighs, shoulders, etc.).

The Resistance Force of the Anterior Cruciate Ligament during Pull Probing Is Related to the Mechanical Property

There are various methods for reconstructing the anterior cruciate ligament (ACL) from other muscles or tendons. Initial tension of the reconstructed ACL is one of the key elements affecting postoperative outcomes. However, tension cannot be measured after graft fixation. The only intraoperative assessment is pull probing, which is performed by pulling joint soft tissues with the arthroscopic probe and can be measured quantitatively. Therefore, its value might be used as an alternative value for the mechanical property of the ACL. Using a probing device one author developed to measure the resistance force of soft tissues quantitatively while probing, we measured the resistance force of dissected ACLs and used tensile testing to investigate the correlation between the resistance force and the mechanical property of the ligaments. According to the results, when a certain amount of tension (strain; 16.6%) was applied, its mechanical properties were moderately correlated (r = 0.56 [p = 0.045]) with the probing force. Therefore, the tension of the reconstructed ACL after fixation under real ACL reconstruction surgery can be derived from the value of the probing device.

Optimal Wire Myography Normalization for the Rat Dorsal Penile, Internal Pudendal and Internal Iliac Arteries

In functional arterial studies using wire myography, the determination of a vessel’s standardized normalization factor (factor k) is an essential step to ensure optimal contraction and relaxation by the arteries when stimulated with their respective vasoactive agents and to obtain reproducible results. The optimal factor k for several arteries have been determined; however, the optimal initial tension and factor k for the arteries involved in erection remains unknown. Hence, in the present study we set out to determine the optimal factor k for the internal iliac artery, proximal and distal internal pudendal artery (IPA), and dorsal penile artery. After isolating, harvesting, and mounting the arteries from male Sprague-Dawley rats on a multi wire myograph, we tested arterial responsivity to high K+-stimulation when the factor k was set at 0.7, 0.8, 0.85, 0.9, 0.95, 1.0, 1.1, and 1.2 to determine the factor k setting that results in the greatest K+-induced active force production for each vessel type. The data showed the optimal factor k is 0.90-0.95 for the dorsal penile, distal internal pudendal and internal iliac arteries while it is 0.85-0.90 for proximal internal pudendal artery. These optimal values corresponded to initial passive tension settings of 1.10±0.16 - 1.46±0.23, 1.28±0.20 - 1.69±0.34, 1.03±0.27 - 1.33±0.31, and 1.33±0.31 - 1.77±0.43 mN/mm for the dorsal penile, distal IP, proximal IP, and internal iliac arteries, respectively.

Numerical calculation and study of differential equations of muscle movement velocity based on martial articulation body ligament tension

The paper analyses the impact of ligament stretch and tension on the speed of movement in martial arts from the perspective of sports physiology. It establishes the numerical relationship between the peak impact value of the ligament speed and the differential equation of the flexibility of the joints in the initial stage of tension (impact peak). It was found that the differential equation of the ligament tension of the movement is formed after the movement is stable, which cannot reflect the flexibility of the ligament and the mastery of the movement. In this paper, a tension calculation model for ligament equilibrium is established by using a kinetic method of motion. Although it is a static equation, continuous use can obtain dynamic effects. The simulation proves that the initial tension change is more realistic.

Uplift resistance capacity of anchor piles used in marine aquaculture

Anchor piles are widely used in marine aquaculture, and the safety is largely determined by the uplift resistance capacity,especially in harsh ocean environments. However, there are few practical guides to the design and installation of the anchor piles for mooring the body of marine aquaculture equipment. Laboratory experiments were conducted to investigate the effect of the initial tension angle, pile diameter, embedded depth, and pile configuration on the uplift resistance capacity of anchor piles under oblique loads. CCD camera and load cell were utilized to measure the corresponding displacement and load, respectively. The results show that increasing the initial tension angle of circular and square single piles can significantly improve the uplift resistance capacity. The failure load of the square single pile was slightly higher than that of the circular single pile. Increasing the pile diameter can effectively improve the failure load and delay the development speed of the pile top displacement. Increasing the embedded depth can effectively improve the failure load and increase the lateral displacement of the pile top. The uplift resistance capacity of the dual anchor piles was better than that of the single anchor piles. The layout configuration has little effect on the failure load, but has a large effect on the displacement development.

Determination of the Natural Frequency of the Model Spindle System with Active Regulation of the Initial Tension of the Bearings

This article presents a test stand with a model high-speed spindle equipped with a system of active control of the preload of the bearings. This preload was changed by means of three piezo actuators. The work presents the results of tests during which the commercial Abacus measuring equipment from Data Physics was used. Its application has shown that the spindle system with angular contact ball bearings is responsive to changes in the preload value of these bearings. The change preload resulted in a change in the value of the resonant frequency of the system and its amplitude. This article presents the dependence between the variable value of the preload of the bearings and the corresponding values of the resonance frequency and amplitude of the spindle system. The use of the Abacus measuring equipment for testing allowed for the preparation of a model showing the dynamic behavior of the spindle. The system was forced by a signal with known parameters, and the response to this excitation was recorded at eleven points located on the surface of the entire spindle.

COMPUTER IMPLEMENTATION OF RECURSION ALGORITHM DETERMINATION OF THREAD TENSION DURING FORMATION OF MULTILAYER FABRICS FROM POLYETHYLENE THREADS

Multilayer fabrics made of polyethylene threads are widely used for products of real property and tactical equipment of servicemen capable of protecting the human body from the influence of firearm, cold, cutting, spiny weapons, shock and shock-fractional influences. Optimization of the process of their manufacture is to optimize the tension of the main polyethylene threads in front of the formation zone. To do this, it is necessary to determine the change in relative tension on zones of filling of polyethylene threads on a loop. The execution of this complex task should be based on the use of specially designed computer programs. Taking into account the specifics of the processing of threads on a weaving machine, when determining the relative tension in each individual zone, it is necessary to use a recursion algorithm when the initial tension of the thread from the previous zone will be input for the next zone. Designing new and improvement of existing technological processes of processing polyethylene complex threads on weaving machines requires a change in relative tension on zones of refueling of basic threads. The execution of this complex task should be based on the use of specially designed computer programs using a recursion algorithm. Determination of the change in relative tension on zones of filling of polyethylene complex threads on weaving machines, taking into account the material of the guide, will improve the technology of manufacturing multilayer fabrics that are used to manufacture products of real property and tactical equipment of servicemen capable of protecting the human body from the influence of firearms, cold, cutting, spiny weapons, shock and shock-fractional influences. Improvement of existing technological processes of processing polyethylene complex threads on weaving machines will reduce the downtime that arise when breaking the threads. This negatively affects the productivity of weaving machine tools, reduces the quality of multilayer tissues. Minimization of tension in each line of refueling line of basic polyethylene complex threads will reduce the likelihood of a cliff of the thread, which is important for improving technological processes from the position of increasing the productivity of weaving machine tools and the quality of multilayer tissues. Mathematical provision of a computer program requires the development of thread interaction models with surfaces of scala, framing guides, holes of the remission framework taking into account the real physical and mechanical properties of complex threads and yarns and their real geometric and constructive parameters. The main factor affects the growth of the tension of polyethylene complex threads is the force of friction. It characterizes the friction properties of the threads and conditions of their interaction with the surfaces of the scala, framing guides, holes of the striped frames.