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robot assisted, fixation, percutaneous, fracture, femoral neck
Abdulrahman O. Al-Naseem, Ahmed R. Gonnah , Hussain Al-Ali, Abdulaziz O. Al-Naseem, Irfan Siddique
Cite this article as: Al-Naseem A O, Gonnah A R, Al-Ali H, et al. (April 18, 2022) Robot-Assisted Versus Conventional Freehand Fluoroscopy-Guided Percutaneous Screw Fixation in Femoral Neck Fractures: A Systematic Review and Meta-analysis. Cureus 14(4): e24258. doi:10.7759/cureus.24258
Robotic-assisted navigation for percutaneous femoral neck fracture fixation is a new technology that has shown enhanced intraoperative and postoperative outcomes compared to the conventional freehand fluoroscopy-guided technique. The authors aim to compare robot-assisted femoral neck fracture fixation to conventional freehand fluoroscopy-guided repair. Electronic databases were searched, identifying all observational studies comparing outcomes of both groups. Using the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines, a systematic review and meta-analysis were conducted. The primary outcomes included operative duration (minutes), intraoperative bleeding (mL), fluoroscopy exposure, and frequency of intraoperative drilling. The secondary outcomes included Harris scores, healing rate and time, screw accuracy, and postoperative complications. Seven observational studies were identified, enrolling 506 patients. There was a significant difference between the robot-assisted and conventional groups in terms of intraoperative blood loss (mean difference (MD) = -18.83, p ≤ 0.05), fluoroscopy exposure (MD = -1.81, p ≤ 0.05), and intraoperative drilling frequency (MD = -7.35, p < 0.05). There was no significant difference in operative duration between the groups (MD = -0.21, p = 0.66). Most secondary outcomes were improved in the robot-assisted group. Overall, robot-assisted fixation was superior in terms of safety and efficacy.
Fractures of the femoral neck (NOF) are a specific type of intracapsular hip fractures [1] that occur most commonly due to low-energy falls in the elderly [2]. They can also occur in the younger population (<60 years), accounting for 2%-11% of cases [3], secondary to high-energy trauma such as traffic accidents and falls from significant heights [4]. Risk factors vary in the different age groups presenting with this injury. For instance, NOF in the elderly are more common in postmenopausal Caucasian females who have reduced physical activity and osteoporosis [1,4]. Younger patients with chronic debilitating conditions including seizures, impaired balance, or osteopenia (secondary to malnutrition, hemiplegia, or medications) are also at a higher risk [4]. Additionally, smoking and alcoholism have been associated with low peak bone mass and hence increased risk of hip complications [4]. Fractures are evaluated using plain films and computed tomography (CT) scans and classified according to Garden and Pauwel classifications [1], which are used to determine the management. Surgery is the mainstay of management.
Operative methods include open reduction and internal fixation (ORIF) in younger patients with displaced fractures [1]. Interruption of the blood supply (medial circumflex arteries) to the femoral head is concerning in these patients as it can lead to avascular necrosis (AVN) [1]. Patients with displaced fractures usually present with vertically oriented Pauwel type 3 fractures due to trauma [1], where percutaneous sliding and cannulated hip screws can be more beneficial [1]. Non-displaced fractures are usually managed similarly and most commonly with cannulated hip screws, which reduces the risk of AVN and nonunion [1]. Patients with displaced hip fractures undergo hemi- or total hip replacement, depending on their activity status [1]. The most common site for hip fracture is the trochanteric region and is usually stabilized by osteosynthesis using the sliding compression hip screw [5].
Current techniques involve placing the cannulated screw into the femoral neck/head with the help of a guidewire [5]. The conventional approach involves inserting the guidewire into the femoral head/neck using mobile C-arm fluoroscopy to obtain posterior-anterior (PA) and lateral-to-medial views of the fractured hip [5]. The lack of 3D X-ray images incurs a depth perception problem [5]. Postoperative follow-up outcomes have shown a 10% failure rate due to difficulties in the initial insertion of the guidewire, leading to excessive drilling and bleeding, prolonged procedure and fluoroscopy exposure time, and an increased risk of infection [5]. Additionally, bone damage can arise, which can also have implications for postoperative recovery [5]. Furthermore, computer-assisted surgery was previously trialled in practice to provide 3D images of the path of the guidewire insertion; however, the absence of the robotic manipulator drill did not solve the problem of precise insertion and was associated with more complications [6].
Recently studies on minimally invasive robotic-assisted orthopedic surgery have shown better outcomes in the surgeries of the sacroiliac joint [7] and spinal [8] percutaneous screw placement compared to the freehand technique. A study by Al-Naseem et al. has shown robot-assisted fixation for posterior pelvic ring injuries to have better intraoperative outcomes [9]. The guidewire insertion stage is the only targeted stage, involving intraoperative calibration and trajectory planning [5]. Calibration is achieved via the fluoroscopy-based intraoperative registration scheme and X-ray photogrammetry to introduce artificial calibration features (fiducials) [5] at which the guidewire can be inserted safely with minimal complications and effectively by drilling at a maximal 0.88 mm reconstruction error [5]. The position and direction of the sleeve are checked using intraoperative anteroposterior (AP) and lateral fluoroscopic X-ray images, which are also used to examine screw positioning (parallelism and neck-width coverage), allowing for position adjustment in cases of bias [5]. The normal steps are then carried out by the surgeon. Postoperative management regimens are similar in both groups, including prophylactic antibiotics for 24 hours after surgery, repeat anteroposterior pelvic and lateral hip radiographs at regular intervals, and physical therapy, to allow for weight-bearing walking once the fracture fully healed with evidence on X-ray [5]. The application of robot-assisted surgery in practice has been evaluated in some studies and a meta-analysis reviewing spine fixation [7].
A systematic review and meta-analysis were conducted as per the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines [10].
All randomized control trials and observational studies comparing robot-assisted percutaneous cannulated screw fixation with conventional freehand screw fixation for femoral neck fractures were included. Robot-assisted fixation was the intervention group of interest, and conventional freehand fixation was the comparator.
The primary outcomes included operation duration (minutes), intraoperative bleeding (mL), and intraoperative fluoroscopy and intraoperative drilling frequency. Operation duration was defined as the total time in minutes from the start of the aseptic technique to suture incision. The total volume of blood in milliliters (mL) collected in the suctioning machine was used as a measure of intraoperative bleeding. Fluoroscopy was also assessed using time in seconds. The frequency of intraoperative drilling was defined as the number of guidewire insertions for screw pathway planning.
The secondary outcomes included the Harris score, fracture healing rate and time, screw accuracy, and postoperative complications. Screw accuracy included anterior-posterior and lateral parallelism, as well neck area held by screws. Complications such as femoral head penetration and avascular necrosis were summarized in a table.
Two authors (AN and AG) independently searched the following electronic databases: MEDLINE, Embase, and the Cochrane Central Register of Controlled Trials (CENTRAL). The last search was run on March 24, 2021. Thesaurus headings, search operators, and limits in each of the above databases were adapted accordingly. In addition, the World Health Organization International Clinical Trials Registry (http://apps. who.int/trial search/), ClinicalTrials.gov (http://clinical- trials.gov/), and ISRCTN Register (http://www.isrctn. com/) were searched for details of ongoing and unpublished studies. No language restrictions were applied. Medical Subject Headings (MeSH) terms including “robot,” “fixation,” “fracture,” and “femoral” were utilized. The bibliographic lists of articles of relevance were reviewed.
The titles and abstracts of articles identified from the literature searches were assessed independently by two authors (AN and AG). The full texts of relevant reports were retrieved, and those articles that met the eligibility criteria of our review were selected. Discrepancies in study selection were resolved by discussion between the authors.
An electronic data extraction spreadsheet was created according to Cochrane’s data collection form for intervention reviews. Pilot testing of the spreadsheet was carried out in randomly selected articles, and adjustments were made accordingly. The data extraction spreadsheet provided data on the study characteristics (author, publication year, publication journal, country of study, study design, study size, clinical condition of the study participants, intervention type, and comparison), baseline demographics of the included populations (age and gender), and primary and secondary outcome data. The results were obtained and recorded by two authors separately (HA and AZ). Disagreements were solved by discussion.
Data synthesis was conducted via the Review Manager 5.4 software. Data extracted were input into Review Manager by two authors independently (AN and AZ). The analysis involved was mainly based on the fixed-effect model. The random-effect model was only used when heterogeneity was high (greater than 75%). The results were reported in forest plots with 95% confidence intervals (CIs).
For dichotomous outcomes, the odds ratio (OR) was calculated between the two groups. The OR is the odds of an event in the robot-assisted group compared with the conventional group. An OR of less than 1 for avascular necrosis would favor the robot-assisted group, an OR of more than 1 would favor the conventional group, and an OR of 1 would favor neither group. An OR of more than 1 for fracture healing rate would favor the robot-assisted group, an OR of less than 1 would favor the conventional group, and an OR of 1 would favor neither group.
For continuous outcomes, the mean difference (MD) was calculated between the two groups. A positive MD for the Harris score and neck area held by screws would favor the robot-assisted group, a negative MD would favor the conventional group, and an MD of 0 would favor neither group. For all other outcomes, a negative MD would favor the robot-assisted group, a positive MD would favor the conventional group, and an MD of 0 would favor neither group.
Heterogeneity among the studies was assessed using the Cochran Q test (χ2). Inconsistency was quantified by calculating I2 and interpreted using the following guide: 0%-25% may represent low heterogeneity, 25%-75% may represent moderate heterogeneity, and 75%-100% may represent high heterogeneity.
Figure 1 demonstrates our search strategy, which retrieved 716 studies. After a thorough screening process of the retrieved articles, the authors identified seven studies in total that met the eligibility criteria.
The PRISMA diagram details the search and selection processes applied during the overview.
PRISMA: Preferred Reporting Items for Systematic Reviews and Meta-Analyses
Description of the Included Studies
Seven studies were included, consisting of a total of 506 patients. Tong et al. (2016) [11] and Cao et al. (2017) [12] were the first two studies to look at robot-assisted femoral neck fixation. All studies except for Duan et al. (2019) [13], He et al. (2019) [14], and Wan et al. (2021) [15], which were prospective studies, were retrospective cohort studies. Duan et al. [13] was a prospective cohort study, while He et al. [14] and Wan et al. [15] were the only randomized control trials. Wang et al. (2019) [16] and Zhu et al. (2021) [17] were the largest studies with 128 and 133 patients each compared to the other studies that had a number of included patients in the range of 3-60. The studies aimed to assess the efficacy and safety of the included studies looking mainly at intraoperative outcomes. Reporting of complications has been noted to be poor among the studies. Further details can be found in Table 1.
Intraoperative outcomes including operative duration (minutes), intraoperative bleeding (mL), and frequency of intraoperative fluoroscopy and drilling were assessed. These outcomes are summarized in Table 2.
N: number, NR: not reported, RAF: robot-assisted fixation, CFF: conventional freehand fixation
In Figure 2, operation duration was reported in seven studies, enrolling 506 patients. There was no statistically significant difference seen in the mean difference analyses, showing a similar operative duration in both intervention and control groups (MD = -0.21, 95% CI = -1.17 to 0.75, P = 0.66). A high level of heterogeneity was found among the studies (I2 = 96%, P < 0.00001). He et al. reported operation duration as time for cannulated screw insertion rather than total operation duration, but the method was standardized in the conventional freehand group within the same study [14].
In Figure 3, intraoperative bleeding was reported in six studies, enrolling 446 patients. There was a statistically significant difference seen in the mean difference analyses, showing less intraoperative bleeding in the robot group (MD = -18.83, 96% CI = -28.71, -8.96, P = 0.0002). A high level of heterogeneity was found among the studies (I2 = 98%, P < 0.00001). Intraoperative bleeding was not reported in He et al. [14].
In Figure 4, the frequency of fluoroscopy was reported in seven studies, enrolling 506 patients. There was a statistically significant difference seen in the mean difference analyses, showing reduced exposure to fluoroscopy in the robot-assisted group compared to the conventional group (MD = -1.81, 95% CI = -2.74 to -0.88, P = 0.0001). A high level of heterogeneity was found among the studies (I2 = 95%, P < 0.00001). He et al. reported fluoroscopy exposure in terms of time during guide pin insertion (seconds), which was accounted for using the standardized MD [14].
In Figure 5, the frequency of intraoperative drilling was reported in 6 studies enrolling 373 patients. There was a statistically significant difference seen in the mean difference analyses favoring the robot-assisted group (MD = -7.35, CI = -11.57 to -3.12, P = 0.0007). A high level of heterogeneity was found among the studies (I2 = 91%, P < 0.00001).
There were three distinct categories of secondary outcomes. Healing and recovery included the Harris score and fracture healing time and rate. Screw placement accuracy included AP and lateral parallelism and neck-width coverage, while the postoperative category included complications such as avascular necrosis and postoperative hospital stay.
Healing and recovery: In Figure 6, the Harris score was reported in six studies, enrolling 446 patients. There was a statistically significant difference seen in the mean difference analyses, favoring the robot-assisted group (MD = 3.54, 95% CI = 1.09 to 5.99, P < 0.00001). A medium level of heterogeneity was found among the studies (I2 = 52%, P < 0.0001). He et al. [14] reported no significant differences in Harris scores between the two groups. Due to absent SDs, this study was not included in the quantitative analysis.
In Figure 7, the fracture healing time was reported in four studies, enrolling 271 patients. There was a statistically significant difference seen in the mean difference analyses, favoring the robot-assisted group (MD= -0.54, 95% CI = -1.10 to -0.03, P = 0.06). A high level of heterogeneity was found among the studies (I2 = 72%, P = 0.003).
In Figure 8, the fracture healing rate was reported in seven studies, enrolling 524 patients. There was a statistically significant difference seen in the odds ratio analyses, favoring the robot-assisted group (OR = 0.28, 95% CI = 0.09 to 0.87, P = 0.03). A low level of heterogeneity was found among the studies (I2 = 0%, P = 0.67). The odds ratio was not estimable for Wang et al. [16] as there was 100% healing in both groups and was not included in the plot.
Screw placement accuracy: This was assessed in the AP direction and also laterally as seen in Figure 9 and Figure 10. Table 3 summarizes outcomes with regard to screw placement accuracy. Patients in the robotic-assisted fixation group experienced a significant improvement in the functional scoring system, reported as an increase in the parallelism score by Duan et al. [13]. Neck-width coverage, which has been reported in Duan et al. [13], is significantly greater in the robot-assisted group.
In Figure 9, AP screw placement accuracy was reported in three studies, enrolling 231 patients. No statistically significant difference was seen between the robot and conventional groups (MD = -1.65, 95% CI = -4.29 to -0.99, P = 0.22). A high level of heterogeneity was found among the studies (I2 = 100%, P < 0.0001).
In Figure 10, lateral screw placement accuracy was reported in three studies, enrolling 231 patients. A statistically significant difference was seen, favoring the robot-assisted group (MD = -1.43, 95% CI = -2.66 to -0.20, P = 0.02). A high level of heterogeneity was found among the studies (I2 = 98%, P < 0.00001).
Postoperative complications: Postoperative complications have been reported in all five studies and can be seen in Table 4. Overall, robot-assisted fixation is associated with fewer complications. The incidence of avascular necrosis is significantly greater in the conventional group compared to the robot-assisted group in Wang et al. [16], He et al. [14], and Zhu et al. [17]. No significant differences were seen between the groups in other studies. According to Duan et al. [13] and Zhu et al. [17], the robot-assisted group was less likely to have femoral head penetration. No significant differences were seen between the groups in other studies. Except for Wang et al. [16], all studies showed that conventional fluoroscopy-guided treatment increases the likelihood of nonunion compared to the robot-assisted group. Screw fixation loosening has been reported in all studies. In He et al. [14], Wang et al. [16], and Wan et al. [15], the conventional treatment is linked with a greater likelihood of screw fixation loosening. No significant differences were seen between the groups in other studies. He et al. [14] showed that secondary fracture displacement was more likely in the conventional group. No significant differences were seen between the groups in other studies. According to He et al. [14], patients in the robot-assisted group were more likely to have limb length shortening post-surgery. No episodes of infection or neurovascular injury were reported in any of the five studies. Zhu et al. [17] found that patients without comorbidities undergoing robot-assisted femoral neck fracture fixation have a statistically significant shorter postoperative hospital stay.
NR: not reported, RAF: robot-assisted fixation, CFF: conventional freehand fixation, AVN: avascular necrosis, NV: neurovascular
Methodological Quality and Risk of Bias Assessment
As seen in Table 5, the Cochrane Collaboration tool was utilized to assess the quality of the randomized studies. Overall, both studies have a low risk of bias in most areas; however, due to a lack of information in the study methodologies, selection bias and performance bias were rated as unclear for both groups. Detection bias was also unclear for Wan et al. [15].
The quality of the nonrandomized studies was assessed using the Newcastle-Ottawa Scale (NOS) [18] (Table 6), which uses a star system to analyze selection, comparability, and outcome. The selection, comparability, and outcome domains have a maximum star score of four, two, and three stars, respectively. Overall, all three studies were of high quality based on the Agency for Healthcare Research and Quality (AHRQ) standards [19]. All five nonrandomized studies (Tong et al., Cao et al., Duan et al, Wang et al., and Zhu et al.) [11,12,13,16,17] have shown a high quality of patient selection with clear inclusion and exclusion criteria. This is represented by a score of four stars (Table 6). Patients who underwent both robot-assisted fixation and conventional freehand surgery were derived from the same surgical records. Both groups did not have the outcome of interest at the start of the study. The study compares the effectiveness of robot-guided surgery to manual fixation in the control group, exhibiting clear comparability. Several patient factors such as age, fracture subtype, and causes were standardized and controlled. All patients continued until the end of follow-up, avoiding attrition bias. The length of follow-up was adequate but not enough in the studies and was required to be longer to assess efficacy outcomes such as healing rate and long-term complications such as AVN.
In a pooled analysis of seven trials [11-17], robotic-assisted surgery was associated with a decrease in intraoperative bleeding loss [11,12,13,15,16,17], due to the lower number of holes drilled and hence less trauma as reported in both Duan et al. [13] and Wan et al. [15]. The frequency of intraoperative fluoroscopy use was significantly reduced in the robotic-assisted surgery arm, as shown in the studies Tong et al. [11], Cao et al. [12], Duan et al. [13], He et al. [14], Wan et al. [15], and Wang et al. [16]. This results in less radiation exposure and greater safety for both patients and surgical staff [13]. The robot-assisted device had no overall effect on the operation duration, despite being significantly lower in studies by Wan et al. [15] and Wang et al. [16], and slightly shorter as reported by Duan et al. [13]. However, the operation duration was significantly increased in the study conducted by Zhu et al. [17] due to the additional surgical steps associated with the new robotic system, as well as the surgeons’ lack of expertise in dealing with the manipulator in the early period [8,15]. The operation duration extended from approximately 60 to 90 minutes in all studies, but the mean time taken in the conventional group in one trial [17] was much shorter compared to others and can potentially be due to varying skill levels between surgeons, lower case complexity, and less intraoperative complications. Future studies are needed, with adequate training and more staff to perform the planning steps [20] and the inclusion of larger sample sizes to accurately evaluate the effect on the operation duration, as it stays undetermined.
In terms of postoperative outcomes, the Harris hip score, which can be used as a prognostic scale [13,15,16,17], showed significantly higher outcomes in robot-assisted fixation in four of the studies; the higher the score, the better the outcome [21]. The main factors affecting prognosis postoperatively include fracture classification by both Pauwel and Garden classifications and age [17]. Nonunion and AVN complications are rare in patients with Garden type I and II compared to type III and IV [17]. Similar results were yielded according to the Pauwel classification [14]. Regardless of the age or fracture subtype, robot navigation surgery was associated with a lower incidence of nonunion [12,13,17] and AVN [14,16,17], as suggested by three studies [14,16,17]. AVN complications can arise from multiple or inaccurate guide needle insertion [1] or fixating screw [14,17], where it penetrates the femoral head and blood supply [1]. Guidewire insertion frequency was lower and more accurately positioned in the robot-assisted surgery group, as shown in two studies [13,16]. This was due to the device having a correction function, carrying out adjustments in the case of guide needle deviation, hence improving safety. As a result, screw parallelism when arranged in an “inverted angle” effect was significantly improved [13,14,17], as well as the neck-width coverage, due to the maximal spread of the three parallel screws [19,20] was significantly enlarged. Clinically, this has been shown to enhance the stability of fracture fixation [13,22,23], which is important for fracture compression and healing [24]. Additionally, the robot-guided surgery resulted in a reduction in the healing time [13,15], as well as better outcomes in the healing rate, accounting for more patients healing completely [13,15,17]. Postoperative healing time was related to drilling frequency [5]. With the frequency being lower when utilizing robotic guidance, the healing time and rate results are consistent with what has been shown in both studies in terms of drilling frequency [13,15]. Moreover, no cases of wound infection and vascular or nerve damage were reported, exhibiting a high level of safety for patients and hence avoiding severe adverse effects that can have debilitating consequences on their quality of life [11-17]. Furthermore, more cases of screw loosening or dislocation occurred in the conventional freehand surgery group, which was potentially attributed to the lower accuracy and higher frequency of screw insertion [14-16]. Finally, two cases of secondary fracture displacement occurred in the conventional surgery group compared to none in the robotic-assisted group, as reported by He et al. [14]; however, it was not a considerable complication in the other studies. This can further emphasize the greater level of accuracy and postoperative stability offered by the robotic assistance, resulting in fewer complications such as malunion, fracture relapses, and potential avascular necrosis as outlined in our studies [11-17].
Currently, robotic-assisted surgery is becoming more widely used in many orthopedic surgeries [9,25,26] and has shown superior results when compared to freehand surgery. Better outcomes with regard to reduced radiation exposure, greater healing rates, and potentially reduced hospitalization stay, as well as improved postoperative stability and mobilization, would support the theory of considering robotic-guided surgery as gold standard management in future practice, despite being a more costly option [13]. Additionally, manipulator’s complications were far less common [17]. However, repeated practice is required as it is believed to reduce the operation time [11-17]. This can have an impact on the efficiency, reducing the waiting lists and increasing bed availability, due to better recovery rate and hence faster discharge. This device can reduce the costs related to complications and longer hospital stays and be deemed cost-effective.
A strength of the studies included is having a good range of defined outcomes that are significant, clearly favoring the new invention. Additionally, effective selection of the cohorts was derived from secure surgical records in the nonrandomized studies, choosing patients who are representative of both groups being compared. Some variables, such as age, fracture side, subtype, and causes, were standardized (no significant difference) to avoid confounding bias. Follow-up of all patients continued until the end, avoiding attrition bias. Limitations included a short follow-up period in the studies as complications such as AVN usually occur 2-3 years after NOF [23]. This can also result in inaccuracies when determining the healing rate, at which patients healed completely, as it can take time. Studies with a shorter follow-up period would show less significance. Additionally, all studies were single-center, and five [11,12,13,16,17] were not randomized. Sample sizes were small as well. For improvement, further multicenter randomized controlled trials with larger sample sizes and follow-up periods are recommended. Moreover, some outcomes were only evaluated by two studies, hence being underpowered, and the units reported were sometimes not standardized, making it harder to combine the results occasionally.
Despite being still under development, robot-assisted surgery has so far proven to be a more effective technique compared to the manual surgical technique, as displayed by the promising results of our meta-analysis. Intraoperative blood loss and drilling and fluoroscopy frequency were significantly reduced in the robot-assisted group; however, there was no significant difference in operation duration between robot-assisted and conventional screw fixation. Robot-assisted fixation is surgically more accurate and has better postoperative Harris scores and healing rates, although there was no significant difference in terms of healing times. Postoperative complications, including avascular necrosis and nonunion, are reduced in the robot-assisted group. Improved patient safety and quality of life were evidenced, further emphasizing the benefit this device can have on the healthcare system. More randomized controlled trials that have higher-quality evidence are required in the future to evaluate the outcomes that have been undetermined in this analysis. This would have allowed adequate training for surgeons after a longer implementation of the robotic systems in the healthcare system, providing a better insight into their effectiveness.
School of Medicine, University of Manchester, Manchester, GBR
School of Medicine, University of Liverpool, Liverpool, GBR
Orthopaedic Surgery Department, McGill University Health Centre, Quebec, CAN
School of Medicine, University of Glasgow, Glasgow, GBR
Department of Complex Spinal Surgery, Salford Royal National Health Services (NHS) Foundation Trust, Manchester, GBR
Conflicts of interest: In compliance with the ICMJE uniform disclosure form, all authors declare the following: Payment/services info: All authors have declared that no financial support was received from any organization for the submitted work. Financial relationships: All authors have declared that they have no financial relationships at present or within the previous three years with any organizations that might have an interest in the submitted work. Other relationships: All authors have declared that there are no other relationships or activities that could appear to have influenced the submitted work.
Al-Naseem A O, Gonnah A R, Al-Ali H, et al. (April 18, 2022) Robot-Assisted Versus Conventional Freehand Fluoroscopy-Guided Percutaneous Screw Fixation in Femoral Neck Fractures: A Systematic Review and Meta-analysis. Cureus 14(4): e24258. doi:10.7759/cureus.24258
Peer review began: January 10, 2022 Peer review concluded: April 17, 2022 Published: April 18, 2022
© Copyright 2022 Al-Naseem et al. This is an open access article distributed under the terms of the Creative Commons Attribution License CC-BY 4.0., which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
The PRISMA diagram details the search and selection processes applied during the overview.
PRISMA: Preferred Reporting Items for Systematic Reviews and Meta-Analyses
N: number, NR: not reported, RAF: robot-assisted fixation, CFF: conventional freehand fixation
NR: not reported, RAF: robot-assisted fixation, CFF: conventional freehand fixation, AVN: avascular necrosis, NV: neurovascular
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