直接前方入路与后外侧入路全髋关节置换治疗股骨颈骨折的疗效比较及术后髋关节功能的影响因素分析

摘要 目的：比较直接前方入路与后外侧入路全髋关节置换治疗股骨颈骨折的疗效及术后髋关节功能的影响因素分析。方法：选取2019年5月至2021年12月徐州医科大学附属医院收治并行全髋关节置换治疗股骨颈骨折患者96例,按照手术方法的不同分为直接前方入路组（n=48）和后外侧入路组（n=48）。观察两组围术期指标、并发症发生情况,比较两组治疗前后Harris评分、视觉模拟评分法（VAS）。并应用单因素、多因素Logistic回归分析患者术后髋关节功能的影响因素。结果：直接前方入路组下床时间、切口长度、住院时间显著短于后外侧入路组,术中失血量、术后引流量显著低于后外侧入路组,而手术时间显著长于后外侧入路组（P<0.05）。直接前方入路组术后1、3个月Harris评分显著高于后外侧入路组,VAS评分显著低于后外侧入路组（P<0.05）。两组术后并发症发生率比较,无统计学差异（P＞0.05）。两组治疗6个月后髋关节功能优良率比较,差异无统计学意义（P>0.05）。多因素Logistic回归分析结果显示：体质量指数≥24 kg/m²、术后锻炼时间<3 h/d、合并骨质疏松是接受全髋关节置换治疗的股骨颈骨折患者术后髋关节功能不良的危险因素（P＜0.05）。结论：直接前方入路全髋关节置换术较后外侧入路全髋关节置换术短期内优势明显,表现为对患者的创伤更小,术后疼痛程度较轻,有利于患者的髋关节功能恢复。体质量指数≥24 kg/m²、术后锻炼时间<3 h/d、合并骨质疏松是接受全髋关节置换治疗的股骨颈骨折患者术后髋关节功能不良的危险因素。     

不同剂量右美托咪定联合超声引导下多点髂筋膜间隙阻滞在老年全髋关节置换术中的应用效果分析

摘要 目的：探讨超声引导下多点髂筋膜间隙阻滞联合不同剂量右美托咪定在老年全髋关节置换术（THA）中的应用效果。方法：选取2019年11月-2022年12月北京积水潭医院贵州医院择期行THA的老年患者120例,按照随机数字表法分为A组（n=40）、B组（n=40）、C组（n=40）,三组均接受超声引导下多点髂筋膜间隙阻滞治疗,在此基础上,A组、B组、C组分别给予0.5 μg/kg、1.0 μg/kg、1.5 μg/kg右美托咪定注射液。对比三组临床指标、血流动力学指标、应激反应指标、脑神经损伤情况,观察三组围术期间不良反应发生情况。结果：B组、C组的阻滞消退时间、拔管时间长于A组,首次下床时间短于A组（P<0.05）。B组、C组的阻滞消退时间、拔管时间、首次下床时间对比无差异（P>0.05）。三组麻醉诱导后即刻（T1）~手术结束时（T3）时间点心率（HR）、平均动脉压（MAP）升高后降低（P<0.05）。B组、C组的T1~T3时间点HR、MAP均低于A组,且B组低于C组（P<0.05）。三组T3时间点皮质醇（Cor）、白介素-6（IL-6）、肿瘤坏死因子-α（TNF-α）升高（P<0.05）。B组、C组的T3时间点Cor、IL-6、TNF-α均低于A组,且B组低于C组（P<0.05）。B组、C组的T3时间点中枢神经特异性蛋白（S100β）均低于A组,且B组低于C组（P<0.05）。B组、C组的T3时间点脑源性神经生长因子（BDNF）均高于A组,且B组高于C组（P<0.05）。三组不良反应发生率组间对比无差异（P>0.05）。结论：超声引导下多点髂筋膜间隙阻滞联合1.0 μg/kg右美托咪定在THA中具有更好的麻醉效果,可缩短首次下床时间,减轻机体应激反应、血流动力学波动以及脑部神经损伤。     

七氟烷复合麻醉对老年骨科患者术后早期认知功能的影响

摘要 目的：探讨七氟烷复合麻醉对老年骨科患者术后早期认知功能的影响。方法：选择2017年12月~2019年6月在西安医学院第二附属医院（本院）骨科诊治单侧老年全膝关节置换手术患者112例,随机数字表法分为七氟烷组与对照组,各56例。对照组给予常规静脉注射全身麻醉,在此基础上七氟烷组给予七氟烷吸入麻醉,记录与调查两组术后早期认知功能。结果：经过对比,两组手术时间、术中出血量对比差异无统计学意义(P>0.05),而七氟烷组的术后苏醒时间(7.10±0.22)min、拔管时间(8.65±0.46)min等都显著短于对照组(14.09±1.09)min、(18.76±1.44)min,两组对比有统计学意义(P<0.05)。所有患者在T1、T2、T3与T4时间点的心率和血氧饱和度均表现正常,对比均无统计学意义(P>0.05)。七氟烷组术后1 d、术后14 d的血清白介素(Interleukin,IL)-6、肿瘤坏死因子(Tumor necrosis factor,TNF)-α值显著低于对照组,对比有统计学意义(P<0.05),且两组术后14 d的血清IL-6与TNF-α值均显著低于术后1 d (P<0.05)。术后1个月七氟烷组的认知功能障碍发生率为1.8 %（1/56）,显著低于对照组的12.5 %（7/56）,两组间对比有统计学意义(x²=4.846,P=0.028)。结论：七氟烷复合麻醉在老年骨科患者中的应用能促进患者康复,安全性比较好,能抑制炎症因子的释放,从而减少术后早期认知功能障碍的发生。     

Effects of branched-chain amino acid supplement on knee peak torque and indicators of muscle damage following isokinetic exercise-induced delayed onset muscle soreness

[Purpose] This study aimed to investigate the effects of branched-chain amino acid (BCAA) supplement on delayed onset muscle soreness (DOMS) by analyzing the maximum muscle strength and indicators of muscle damage.[Methods] Twelve men with majors in physical education were assigned to the BCAA group and placebo group in a double-blinded design, and repeated measurements were conducted. DOMS was induced with an isokinetic exercise. Following BCAA administration, the changes in the knee extension peak torque, flexion peak torque, aspartate aminotransferase (AST), creatine kinase (CK), and lactate dehydrogenase (LDH) concentrations were analyzed. The maximum knee muscle strength was measured at the baseline (pre-D0) following BCAA administration for 5 days before exercise (-D5, -4D, -3D, -2D, -1D). In contrast, the post-treatment measurements (D3) were recorded after BCAA administration for 3 days (post-D0, D1, D2). Blood samples were obtained before (pre-D0), immediately after (post-D0), 24 h (D1), 48 h (D2), and 72 h (D3) after the exercise to analyze the indicators of muscle strength. BCAA was administered twice daily for 8 days (5 days and 3 days before inducing DOMS and during the experimental period, respectively).[Results] There was no difference in the flexion peak torque between the groups. However, the BCAA group showed a significantly higher extension peak torque at D3 (second isokinetic exercise), compared to the placebo group (p<.05). There was no difference in AST changes between the groups. Nonetheless, the CK and LDH were significantly reduced in the BCAA group, compared to the placebo group. There was no correlation between the extension peak torque and flexion peak torque. However, the CK and LDH increased proportionately in DOMS. Moreover, their concentrations significantly increased with a decreasing peak torque (p<.01).[Conclusion] An exercise-induced DOMS results in a decrease in the peak torque and a proportional increase in the CK and LDH concentrations. Moreover, the administration of BCAA inhibits the reduction of the extension peak torque and elevation of CK and LDH concentrations. Therefore, BCAA might be administered as a supplement to maintain the muscle strength and prevent muscle damage during vigorous exercises that may induce DOMS in sports settings.     

A Three-Dimensional Musculoskeletal Model of the Human Knee Joint. Part 2: Analysis of Ligament Function

A three-dimensional model of the knee is used to study ligament function during anterior-posterior (a-p) draw, axial rotation, and isometric contractions of the extensor and flexor muscles. The geometry of the model bones is based on cadaver data. The contacting surfaces of the femur and tibia are modeled as deformable; those of the femur and patella are assumed to be rigid. Twelve elastic elements are used to describe the geometry and mechanical properties of the cruciate ligaments, the collateral ligaments, and the posterior capsule. The model is actuated by thirteen musculotendinous units, each unit represented as a three-element muscle in series with tendon. The calculations show that the forces applied during a-p draw are substantially different from those applied by the muscles during activity. Principles of knee-ligament function based on the results of in vitro experiments may therefore be overstated. Knee-ligament forces during straight a-p draw are determined solely by the changing geometry of the ligaments relative to the bones: ACL force decreases with increasing flexion during anterior draw because the angle between the ACL and the tibial plateau decreases as knee flexion increases; PCL force increases with increasing flexion during posterior draw because the angle between the PCL and the tibial plateau increases. The pattern of ligament loading during activity is governed by the geometry of the muscles spanning the knee: the resultant force in the ACL during isometric knee extension is determined mainly by the changing orientation of the patellar tendon relative to the tibia in the sagittal plane; the resultant force in the PCL during isometric knee flexion is dominated by the angle at which the hamstrings meet the tibia in the sagittal plane.     

An improved OpenSim gait model with multiple degrees of freedom knee joint and knee ligaments

Musculoskeletal models are widely used to investigate joint kinematics and predict muscle force during gait. However, the knee is usually simplified as a one degree of freedom joint and knee ligaments are neglected. The aim of this study was to develop an OpenSim gait model with enhanced knee structures. The knee joint in this study included three rotations and three translations. The three knee rotations and mediolateral translation were independent, with proximodistal and anteroposterior translations occurring as a function of knee flexion/extension. Ten elastic elements described the geometrical and mechanical properties of the anterior and posterior cruciate ligaments (ACL and PCL), and the medial and lateral collateral ligaments (MCL and LCL). The three independent knee rotations were evaluated using OpenSim to observe ligament function. The results showed that the anterior and posterior bundles of ACL and PCL (aACL, pACL and aPCL, pPCL) intersected during knee flexion. The aACL and pACL mainly provided force during knee flexion and adduction, respectively. The aPCL was slack throughout the range of three knee rotations; however, the pPCL was utilised for knee abduction and internal rotation. The LCL was employed for knee adduction and rotation, but was slack beyond 20° of knee flexion. The MCL bundles were mainly used during knee adduction and external rotation. All these results suggest that the functions of knee ligaments in this model approximated the behaviour of the physical knee and the enhanced knee structures can improve the ability to investigate knee joint biomechanics during various gait activities.     

The influence of uncemented femoral stem length and design on its primary stability: a finite element analysis

One of the crucial factors for short- and long-term clinical success of total hip arthroplasty cementless implants is primary stability. Indeed, motion at the bone–implant interface above 40 μm leads to partial bone ingrowth, while motion exceeding 150 μm completely inhibits bone ingrowth. The aim of this study was to investigate the effect of two cementless femoral stem designs with different lengths on the primary stability. A finite element model of a composite Sawbones^® fourth generation, implanted with five lengths of the straight prosthesis design and four lengths of the curved prosthesis design, was loaded with hip joint and abductor forces representing two physiological activities: fast walking and stair climbing. We found that reducing the straight stem length from 146 to 54 mm increased the average micromotion from 17 to 52 μm during fast walking, while the peak value increased from 42 to 104 μm. With the curved stem, reducing length from 105 to 54 mm increased the average micromotion from 10 to 29 μm, while the peak value increased from 37 to 101 μm. Similar findings are obtained for stair climbing for both stems. Although the present study showed that femoral stem length as well as stem design directly influences its primary stability, for the two femoral stems tested, length could be reduced substantially without compromising the primary stability. With the aim of minimising surgical invasiveness, newer femoral stem design and currently well performing stems might be used with a reduced length without compromising primary stability and hence, long-term survivorship.     

Towards a patient-specific estimation of intra-operative femoral fracture risk

Abstract

Total Hip Arthroplasty requires pre-surgical evaluation between un-cemented and cemented prostheses. A Patient with intra-operative periprosthetic fracture and another with a successful outcome were recruited, and their finite element models were constructed by processing CT data, assuming elastic-plastic behavior of the bone as function of the local density. To resemble the insertion of the prosthesis into the femur, a fictitious thermal dilatation is applied to the broach volume. Strain-based fracture risk factor is estimated, depicting results in terms of the total mechanical strain expressed using a simple “traffic lights” color code to provide immediate, concise, and intelligible pre-operative information to surgeons.     

Time-dependent elastohydrodynamic lubrication analysis of total knee replacement under walking conditions

This work is concerned with the lubrication analysis of artificial knee joints, which plays an increasing significant role in clinical performance and longevity of components. Time-dependent elastohydrodynamic lubrication analysis for normal total knee replacement is carried out under the cyclic variation in both load and speed representative of normal walking. An equivalent ellipsoid-on-plane model is adopted to represent an actual artificial knee. A full numerical method is developed to simultaneously solve the Reynolds and elasticity equations using the multigrid technique. The elastic deformation is based on the constrained column model. Results show that, under the combined effect of entraining and squeeze-film actions throughout the walking cycle, the predicted central film thickness tends to decrease in the stance phase but keeps a relatively larger value at the swing phase. Furthermore, the geometry of knee joint implant is verified to play an important role under its lubrication condition, and the length of time period is a key point to influence the lubrication performance of joint components.     

Introducing a new staircase design to quantify healthy knee function during stair ascent and descent

The design, manufacture and validation of a new free standing staircase for motion analysis measurements are described in this paper. The errors in vertical force measurements introduced when the stairs interface with a force plate (FP) are less than 0.6%. The centre of pressure error introduced is less than 0.7 mm compared to the error from the FP. The challenges of introducing stair gait into a clinical trial with a limited number of FPs and time limitations for assessment sessions are addressed by introducing this cost effective solution.

The staircase was used in a study to measure non-pathological knee function of 10 subjects performing stair ascent and descent. The resulting knee kinematics and knee joint moments are in agreement with previous studies. The kinematic and joint moment profiles provide a normative range, which will be useful in future studies for identifying alterations in joint function associated with pathology and intervention.