Impact of compression stockings on leg swelling after arthroscopy - a prospective randomised pilot study

Postoperative management following osteotomies around the knee: a narrative review

The present narrative review provides a summary of postoperative therapy modalities and their effectiveness following osteotomies around the knee. The topics that are discussed in the scientific discourse include support of cartilage cell regeneration, pain management, drainage insertion, tourniquet use, pharmacological and mechanical thromboembolism prophylaxis, weight-bearing protocols and bone consolidation. There is evidence for the use of pharmacological thromboembolism prophylaxis and weight-bearing protocols. A standardized postoperative treatment concept following osteotomies around the knee cannot be derived due to lack of evidence for the other topics in current literature.

Should We Suture Arthroscopic Portals? Effects on Intra-articular Fluid Retention

Knee arthroscopy is one of the most common surgical procedures in orthopaedics and especially in sports medicine. Portal problems and effusion after knee arthroscopy have been reported. The fluid retention within the joint in knee arthroscopy can affect clinical outcomes, but there is no consensus on portal management. The studies of portal management in knee arthroscopy have mainly addressed wound healing and cosmetic problems. There is insufficient information in the literature about whether the irrigation fluid used in this effusion contributes to the process. This study investigates whether arthroscopic irrigation fluid is retained in the joint and whether portal-closure management has an effect on effusion. In this randomized, prospective study, 91 patients (46 [50.5%] sutured-portal group and 45 [49.5%] open-portal group) were included. Suprapatellar knee-diameter measurement and the number of times the dressing was changed were used to assess intra-articular fluid collection. The visual analog scale (VAS) score, Oxford knee score, and Knee Society score were used to evaluate knee problems. All portal wounds in both groups healed without any problems. Superficial or deep infection was not observed in either group. There was no statistically significant difference in VAS score, Oxford knee scores, and Knee Society scores between groups. Although there was a decrease in the knee diameter of both groups between the early postoperative period and first postoperative day, a statistically significant difference in knee diameter was found, especially in the open-portal group. There was a significant difference between the groups in terms of the number of dressings used in the first 24 hours after surgery. Leaving portals open may be effective in preventing intra-articular fluid retention. We thus advise leaving the arthroscopy portals open with just a simple dressing for selected patients.

From Anatomy to Complex Reconstruction: A Modern Review on the Medial Collateral Ligament of the Knee

Medial knee injuries are prevalent, especially in young athletes. A detailed history and physical examination are needed to accurately diagnose injuries to the superficial medial collateral ligament (sMCL), deep medial collateral ligament (dMCL), and posterior oblique ligament (POL). The mechanism of medial knee injury often involves a coupled valgus and external rotation force with pain and tenderness across the medial joint line. Valgus stress radiographs assist with the diagnosis of medial knee injuries based on the quantitative extent of medial joint gapping. Specifically, 3.2 mm of increased medial gapping is observed with an isolated grade-III sMCL injury and greater than 9.8 mm of gapping indicates a complete medial knee injury. Nonoperative treatment is recommended for grade-I and II medial knee injuries. Patients with chronic medial knee instability, or a complete tear of the medial knee structures, may require operative treatment. Anatomic surgical techniques have proven to be highly effective in restoring functional knee stability.

Improvement of occupational leg edema and discomforts (RCT)

BACKGROUND: Edema and subjective leg complaints (e.g. pain, heaviness) after long standing or sitting, are defined as orthostatic leg complaints or occupational edema. Compression hosiery should help to prevent or decrease those symptoms. OBJECTIVE: Assess the effects on leg discomforts and leg volume and wearing comfort in two medical below-knee compression stocking types (A vs. B) with an interface pressure of 18 –20 mmHg and a below-knee-low-pressure support stocking (LPSS) with an interface pressure of 8–10mmHg (C). METHODS: Two different types of below-knee medical compression stockings and a LPSS were examined in this randomized, blinded, crossover trial in volunteers having leg discomforts and edema after being in an upright position during the day. Participants were divided into two cohorts, and each type of stocking was worn for three consecutive days in one week with a subsequent washout phase. The assessment of effects and wearing comfort was ascertained by questionnaires. Volume changes in the lower leg were measured with the Bodytronic 600® (Bauerfeind AG, Zeulenroda, Germany). RESULTS: A significant reduction of lower leg volume (mean stocking A: 204.7 ml; mean stocking B: 153.5 ml; mean stocking C: 48.2 ml) and a significant reduction of the life-quality dimension leg-complaints (p <  0.0001) was achieved by all three types of stockings. Compared to the LPSS both compression stockings decreased the lower leg volume significantly more (p <  0.001) and had a significant better fit (p <  0.001). CONCLUSION: Below-knee medical compression stockings with an interface pressure 18–21mmHg and LPSS with an interface pressure of 8–10 mmHg reduce significantly occupational orthostatic edema and leg discomforts which are due to long standing and sitting activities.

The changes of the calf-vein deformation and femoral vein peak velocity during ankle pump exercise with or without graduated compression stockings

Objectives

To analyze the changes of lower limb hemodynamics parameters before and after wearing graduated compression stockings (GCS) during ankle pump exercise in patients preparing for arthroplastic surgery.

Method

The leg veins of 16 patients awaiting arthroplasty were analyzed using a Sonosite M-Turbo ultrasound system during ankle pump exercise with or without GCS. The age of them was 70 ± 7 years (mean ± SD) (range 56—82 years) and body mass index was 25.8 ± 3.0 kg/m2 (range 18.0—30.5 kg/m2). Measured data including the cross-sectional area (CSA), anteroposterior (AP) diameter and lateromedial (LM) diameter of the soleus vein (SV), posterior tibial vein (PTV) and great saphenous vein (GSV). Additionally, the peak velocities of femoral vein (FV) were also measured.

Results

GCS could significantly decrease the cross-sectional area of SV, PTV and GSV in supine position at rest and maximum ankle plantar flexion. But the compression effect of GCS to SV and GSV was not observed during maximum ankle dorsiflexion. It was found that GCS application reduced the peak flow velocity of the femoral vein from 61.85 cm/s (95% CI = 50.94–72.75 cm/s) to 38.01 cm/s (95% CI = 28.42–47.59 cm/s) (P < 0.001) during ankle plantar flexion and decreased the femoral vein in these patients from 80.65 cm/s (95% CI = 70.37–90.92 cm/s) to 51.15 cm/s (95% CI = 42.58–59.73 cm/s) (P < 0.001) during ankle dorsiflexion. But this effect was not significant in supine position at rest.

Conclusions

GCS could significantly reduce the peak flow velocity of the femoral vein during ankle pump exercise in the patients preparing for arthroplastic surgery.

Postoperative Rehabilitation and Return to Sport Following Multiligament Knee Reconstruction

Multiligament knee injuries (MLKIs) are debilitating injuries that increasingly occur in young athletes. Return to sport (RTS) has historically been considered unlikely due to the severity of these injuries. Reporting in the literature regarding objective outcomes following MLKI, including RTS, is lacking, as are clear protocols for both rehabilitation progressions and RTS testing. RTS following MLKI is a complex process that requires an extended recovery duration compared to other surgery types. Progressions through postoperative rehabilitation and RTS should be thoughtful, gradual, and criterion based. After effective anatomic reconstruction to restore joint stability, objective measures of recovery including range of motion, strength, movement quality, power, and overall conditioning guide decision-making throughout the recovery process. It is important to frame the recovery process of the athlete in the context of the severity of their injury, as it is typically slower and less linear. Improved reporting on objective outcomes will enhance our understanding of recovery expectations within this population by highlighting persistent deficits that may interfere with a full recovery, including RTS.

Intermittent pneumatic compression after varicose vein surgery

OBJECTIVE

Intermittent pneumatic compression (IPC) is an established treatment option to remove tissue fluid from patients with lymphedema and chronic venous disease. The effects of IPC applied directly after varicose vein surgery performed with high volumes of tumescent local anesthesia have not been investigated. The aim of the present study was to evaluate the use of postoperative IPC concerning its effects on the leg volume and patient comfort after surgery.

METHODS

We performed an investigator-initiated, single-center, open-label randomized controlled trial. A total of 186 patients indicated for saphenofemoral junction ligation and great saphenous vein or anterior accessory saphenous vein stripping or great saphenous vein redo surgery were randomly assigned 1:1 to the intervention or control group. The patients in the intervention group were treated with IPC at 40 mm Hg for 45 minutes directly after surgery. The outcome measures were the leg volume changes calculated using an optical three-dimensional scanning system (primary objective), quality of life (QoL; Freiburg Life Quality Assessment for chronic venous disease, short form), pain, and extent of ecchymosis with follow-up examinations on days 1 and 7 after surgery.

RESULTS

The patients in both groups had comparable mean leg volume reductions from baseline to day 1 (IPC group, 58.8 mL; control group, 37.4 mL; P = .967) and to day 7 (63.1 mL and 57.0 mL, respectively; P = .546). We also did not observe significant differences between the two groups in QoL and pain. The patients in the IPC group had developed larger areas of ecchymosis compared with the control group (16% vs 13.3% of leg surface, respectively; P = .046), with a tendency toward an increase in pain at 7 days after surgery compared with no IPC application.

CONCLUSIONS

The present randomized controlled trial was designed to evaluate the decongestive effects of a single postoperative session of IPC and its effect on QoL, pain, and ecchymosis in patients who had undergone varicose vein surgery under tumescent local anesthesia. Because no evidence for a benefit from IPC could be found in the present study and increased ecchymosis was found, its standard use after varicose vein surgery cannot be recommended.

Should compression bandage be performed after total knee arthroplasty? A meta-analysis of randomized controlled trials

Background

Compression bandage often is used after total knee arthroplasty (TKA) to alleviate pain, ameliorate swelling, and reduce bleeding. However, there is controversy about its application due to conflicting clinical outcomes and potential compression-related complications. This meta-analysis aimed to answer the question of if compression bandage should be implemented routinely after TKA.

Methods

Relevant randomized controlled trials (RCTs) on compression bandage were comprehensively retrieved utilizing search engines such as PubMed, EMBASE, Web of Science, and the Cochrane Library, up to September 2019. Studies included in the meta-analysis were those that compared post-operative pain score, swelling, total blood loss, pre- and post-operative hematocrit levels differences, range of motion (ROM), and complications, using Review Manager 5.3.0.

Results

Included were seven RCTs, which reported on 511 knees. The pooled results showed the compression bandage group was associated with a greater post-operative pain score during ambulation at 48 h (WMD = 0.70, 95% CI 0.07 to 1.34, P = 0.03), compared with the non-compression bandage group. No statistically significant differences were found between the groups in post-operative pain scores at the other times, swelling, blood loss, ROM, or other complications (P > 0.05).

Conclusions

The current evidence is unable to conclude that compression bandage is necessary after primary TKA. Surgeons routinely undertaking compression bandage should deliberate whether there is enough clinical evidence.