Computer-Assisted Navigation for Orthopedic Procedure - CAM 70196

Description
Computer-assisted navigation in orthopedic procedures describes the use of computer-enabled tracking systems to facilitate alignment in a variety of surgical procedures, including fixation of fractures, ligament reconstruction, osteotomy, tumor resection, preparation of the bone for joint arthroplasty, and verification of the intended implant placement.

Background
IMPLANT ALIGNMENT FOR KNEE ARTHROPLASTY
For TKA, malalignment is commonly defined as a variation of more than 3° from the targeted position. Proper implant alignment is believed to be an important factor for minimizing long-term wear, the risk of osteolysis and loosening of the prosthesis.

Computer-Assisted Navigation (CAN)
The goal of CAN is to increase surgical accuracy and reduce the chance of malposition.

In addition to reducing the risk of substantial malalignment, CAN may improve soft tissue balance and patellar tracking. CAN is also being investigated for surgical procedures with limited visibility such as placement of the acetabular cup in total hip arthroplasty, resection of pelvic tumors and minimally invasive orthopedic procedures. Other potential uses of CAN for surgical procedures of the appendicular skeleton include screw placement for fixation of femoral neck fractures, high tibial osteotomy and tunnel alignment during the reconstruction of the anterior cruciate ligament.

CAN devices may be image-based or non-image-based. Image-based devices use preoperative computed tomography scans and operative fluoroscopy to direct implant positioning. Newer non-image-based devices use information obtained in the operating room, typically with infrared probes. For TKA, specific anatomic reference points are made by fixing signaling transducers with pins into the femur and tibia. Signal-emitting cameras (e.g., infrared) detect the reflected signals and transmit the data to a dedicated computer. During the surgery, multiple surface points are taken from the distal femoral surfaces, tibial plateaus, and medial and lateral epicondyles. The femoral head center is typically calculated by kinematic methods that involve the movement of the thigh through a series of circular arcs, with the computer producing a three-dimensional model that includes the mechanical, transepicondylar and tibial rotational axes. CAN systems direct the positioning of the cutting blocks and placement of the prosthetic implants based on the digitized surface points and model of the bones in space. The accuracy of each step of the operation (cutting block placement, saw cut accuracy, seating of the implants) can be verified, thereby allowing adjustments to be made during surgery.

Navigation involves three steps: data acquisition, registration and tracking.

Data Acquisition
Data can be acquired in three ways: fluoroscopically, guided by computed tomography scan or magnetic resonance imaging or guided by imageless systems. These data are then used for registration and tracking.

Registration
Registration refers to the ability to relate images (ie, radiographs, computed tomography scans, magnetic resonance imaging, or patients' 3D anatomy) to the anatomic position in the surgical field. Registration techniques may require the placement of pins or "fiduciary markers" in the target bone. A surface-matching technique can also be used in which the shapes of the bone surface model generated from preoperative images are matched to surface data points collected during surgery.

Tracking
Tracking refers to the sensors and measurement devices that can provide feedback during surgery regarding the orientation and relative position of tools to bone anatomy. For example, optical or electromagnetic trackers can be attached to regular surgical tools, which then provide real-time information of the position and orientation of tool alignment concerning the bony anatomy of interest.

VERASENSE (OrthoSense) is a single-use device that replaces the standard plastic tibial trial spacer used in TKA. The device contains microprocessor sensors that quantify load and contact position of the femur on the tibia after resections have been made. The wireless sensors send the data to a graphic user interface that depicts the load. The device is intended to provide quantitative data on the alignment of the implant and soft tissue balancing in place of intraoperative "feel."

iASSIST (Zimmer) is an accelerometer-based alignment system with a user interface built into disposable electronic pods that attach onto the femoral and tibial alignment and resection guides. For the tibia, the alignment guide is fixed between the tibial spines and a claw on the malleoli. The relation between the electronic pod of the digitizer and the bone reference is registered by moving the limb into abduction, adduction, and neutral position. Once the information has been registered, the digitizer is removed, and the registration data are transferred to the electronic pod on the cutting guide. The cutting guide can be adjusted for varus/valgus alignment and tibial slope. A similar process is used for the femur. The pods use the wireless exchange of data and display the alignment information to the surgeon within the surgical field. A computer controller must also be present in the operating room.

Due to the lack of any recent studies on pelvic tumor resection, these sections of the rationale were removed from this evidence review in 2016.

Regulatory Status
Because computer-assisted navigation is a surgical information system in which the surgeon is only acting on the information that is provided by the navigation system, surgical navigation systems generally are subject only to 510(k) clearances from the U.S. Food and Drug Administration (FDA). As such, the FDA does not require data documenting the intermediate or final health outcomes associated with computer-assisted navigation. (In contrast, robotic procedures, in which the actual surgery is robotically performed, are subject to the more rigorous requirement of the premarket approval application process.)

A variety of surgical navigation procedures have been cleared for marketing by the FDA through the 510(k) process with broad labeled indications. For example, The OEC FluoroTrak 9800 plus is marketed for locating anatomic structures anywhere on the human body.

Several navigation systems (e.g., PiGalileo™ Computer-Assisted Orthopedic Surgery System, PLUS Orthopedics; OrthoPilot® Navigation System, Braun; Navitrack® Navigation System, ORTHOsoft) have received the FDA clearance specifically for total knee arthroplasty. The FDA cleared indications for the PiGalileo™ system are representative. This system "is intended to be used in computer-assisted orthopedic surgery to aid the surgeon with bone cuts and implant positioning during joint replacement. It provides information to the surgeon that is used to place surgical instruments during surgery using anatomical landmarks and other data specifically obtained intraoperatively (e.g., ligament tension, limb alignment). Examples of some surgical procedures include but are not limited to:

  • Total knee replacement supporting both bone referencing and ligament balancing techniques
  • Minimally invasive total knee replacement."

FDA product code: HAW.

In 2013, the VERASENSE™ Knee System (OrthoSensor) and the iASSIST™ Knee (Zimmer) were cleared for marketing by the FDA through the 510(k) process. FDA product codes: ONN, OLO.

Several computer-assisted navigation devices cleared by the FDA are listed in the table below.

Table 1. Computer-Assisted Navigation Devices Cleared by the U.S. Food and Drug Administration

Device Manufacturer Date Cleared 510(k) No. Indication
Vital Navigation System Zimmer Biomet Spine Inc. 12/02/2019 K191722 Computer-assisted Navigation for Orthopedic Surgery
Stryker Navigation System With Spinemap Go Software Application, Fluoroscopy Trackers And Fluoroscopy Adapters. Spinemask Tracker Stryker Corporation 02/14/2019 K183196 Computer-assisted Navigation for Orthopedic Surgery
NuVasive Pulse System NuVasive Inc. 6/29/2018 K180038 Computer-assisted Navigation for Orthopedic Surgery
VERASENSE for Zimmer Biomet Persona OrthoSensor Inc. 6/7/2018 K180459 Computer-assisted Navigation for Orthopedic Surgery
StealthStation S8 With Spine Software Medtronic 5/01/2017 K170011 Computer-assisted Navigation for Orthopedic Surgery
NuVasive Next Generation NVM5 System NUVASIVE Inc. 3/16/2017 K162313 Computer-assisted Navigation for Orthopedic Surgery
Stryker OrthoMap Versatile Hip System Stryker Corporation 2/23/2017 K162937 Computer-assisted Navigation for Orthopedic Surgery
JointPoint JointPoint Inc. 8/3/2016 K160284 Computer-assisted Navigation for Orthopedic Surgery
ExactechGPS Blue Ortho 7/13/2016 K152764 Computer-assisted Navigation for Orthopedic Surgery
Verasense Knee System OrthoSensor Inc. 4/15/2016 K150372 Computer-assisted Navigation for Orthopedic Surgery
iASSIST Knee System Zimmer CAS 9/11/2014 K141601 Computer-assisted Navigation for Orthopedic Surgery
CTC TCAT(R)-TPLAN(R) Surgical System Curexo Technology Corporation 8/18/2014 K140585 Computer-assisted Navigation for Orthopedic Surgery
Digimatch Orthodoc Robodoc Encore Surgical System Curexo Technology Corporation 5/27/2014 K140038 Computer-assisted Navigation for Orthopedic Surgery

Policy:
The use of computer assisted navigation for orthopedic procedures of the pelvis and appendicular skeleton is a technique that is integral to the primary surgery being performed and, therefore, not eligible for separate reimbursement. When billed, there will be no separate or additional payment for charges associated with computer assistance technology. Reimbursement will be based on the payment for the standard surgical procedure(s).

Examples of charges that are not eligible for separate or additional reimbursement are listed below: 

  • Increased operating room unit cost charges for the use of the computer assisted technology.
  • Charges billed under CPT or HCPCS codes that are specific to robotic assisted surgery, including, but not limited to, 20985, 0054T and 0055T.
  • Providers should not use Modifier 22 Increased Procedural Service to indicate computer assistance as this modifier should only be used to report unusual complications or complexities which occurred during the surgical procedure that are unrelated to the use of a robotic assistance system and must be supported by documentation.

Benefit Application
BlueCard®/National Account Issues
State or federal mandates (e.g., FEP) may dictate that all devices approved by the U.S. Food and Drug Administration (FDA) may not be considered investigational. Therefore, FDA-approved devices may only be assessed on the basis of their medical necessity.

Rationale 
This evidence review was created in February 2004 and has been updated regularly using with searches of the PubMed database. The most recent literature update was performed through March 1, 2023.

Evidence reviews assess the clinical evidence to determine whether the use of technology improves the net health outcome. Broadly defined, health outcomes are the length of life, quality of life, and ability to function, including benefits and harms. Every clinical condition has specific outcomes that are important to patients and managing the course of that condition. Validated outcome measures are necessary to ascertain whether a condition improves or worsens; and whether the magnitude of that change is clinically significant. The net health outcome is a balance of benefits and harms.

To assess whether the evidence is sufficient to draw conclusions about the net health outcome of technology, 2 domains are examined: the relevance, and quality and credibility. To be relevant, studies must represent 1 or more intended clinical use of the technology in the intended population and compare an effective and appropriate alternative at a comparable intensity. For some conditions, the alternative will be supportive care or surveillance. The quality and credibility of the evidence depend on study design and conduct, minimizing bias and confounding that can generate incorrect findings. The randomized controlled trial (RCT) is preferred to assess efficacy; however, in some circumstances, nonrandomized studies may be adequate. RCTs are rarely large enough or long enough to capture less common adverse events and long-term effects. Other types of studies can be used for these purposes and to assess generalizability to broader clinical populations and settings of clinical practice.

For many orthopedic surgical procedures, optimal alignment is considered an important aspect of long-term success. For example, misplaced tunnels in the anterior cruciate ligament or posterior cruciate ligament reconstruction or malalignment of arthroplasty components are some of the leading causes of instability and reoperation. In total hip arthroplasty (THA), the orientation of the acetabular component of the THA is considered critical, while for total knee arthroplasty (TKA), alignment of the femoral and tibial components and ligament balancing are considered important outcomes. Ideally, one would prefer controlled trials comparing the long-term outcomes, including stability and reoperation rates.

Promotion of greater diversity and inclusion in clinical research of historically marginalized groups (e.g., people of color [African-American, Asian, Black, Latino and Native American]; LGBTQIA [lesbian, gay, bisexual, transgender, queer, intersex, asexual]; women; and People with disabilities [physical and invisible]) allows policy populations to be more reflective of and findings more applicable to our diverse members. While we also strive to use inclusive language related to these groups in our policies, use of gender-specific nouns (e.g., women, men, sisters, etc.) will continue when reflective of language used in publications describing study populations.

Computer-Assisted Navigation for Trauma or Fracture
Clinical Context and Therapy Purpose
The purpose of computer-assisted navigation is to provide a treatment option that is an alternative to or an improvement on existing therapies, such as conventional/manual alignment methods, in individuals who are undergoing orthopedic surgery for trauma or fracture.

The following PICO was used to select literature to inform this review.

Populations
The relevant population of interest is individuals who are undergoing orthopedic surgery for trauma or fracture.

Interventions
The therapy being considered is computer-assisted navigation. Computer-assisted navigation in orthopedic procedures describes the use of computer-enabled tracking systems to facilitate alignment in a variety of surgical procedures, including fixation of fractures, ligament reconstruction, osteotomy, tumor resection, preparation of the bone for joint arthroplasty, and verification of the intended implant placement.

Comparators
Comparators of interest include conventional/manual alignment methods. Treatment by means of conventional/manual alignment methods include medical reduction procedures and conventional fluoroscopic guidance (i.e., C-arm fluroscopy).

Outcomes
The general outcomes of interest are symptoms, morbid events, and functional outcomes.

The existing literature evaluating computer-assisted navigation as a treatment for patients who are undergoing orthopedic surgery for trauma or fracture has varying lengths of follow-up. While studies described below all reported at least one outcome of interest, longer follow-up was necessary to fully observe outcomes.

Study Selection Criteria
Methodologically credible studies were selected using the following principles:

  1. To assess efficacy outcomes, comparative controlled prospective trials were sought, with a preference for RCTs.

  2. In the absence of such trials, comparative observational studies were sought, with a preference for prospective studies.

  3. To assess long-term outcomes and adverse events, single-arm studies that capture longer periods of follow-up and/or larger populations were sought.

  4. Studies with duplicative or overlapping populations were excluded.

Review of Evidence
Computer-assisted surgery has been described as an adjunct to pelvic, acetabular, or femoral fractures. For example, fixation of these fractures typically requires percutaneous placement of screws or guidewires. Conventional fluoroscopic guidance (i.e., C-arm fluoroscopy) provides imaging in only 1 plane. Therefore, the surgeon must position the implant in 1 plane and then get additional images in other planes in a trial-and-error fashion to ensure that the device has been properly placed. This process adds significant time in the operating room and radiation exposure. Computer-assisted surgery may permit minimally invasive fixation and provide more versatile screw trajectories with less radiation exposure. Therefore, computed-assisted surgery is considered an alternative to the existing image guidance using C-arm fluoroscopy.

Observational Study
Ideally, investigators would conduct controlled trials comparing operating room time, radiation exposure, and long-term outcomes of those whose surgery was conventionally guided using C-arm versus image-guided using computer-assisted surgery. While several in vitro and review studies had been published,1,2,3 only 2 studies of computer-assisted surgery in trauma or fracture cases were identified.4,5 Computer-assisted navigation for internal fixation of femoral neck fractures was retrospectively analyzed in 2 cohorts of consecutive patients (20 each, performed from 2001 to 2003, at 2 different campuses of a medical center) who underwent internal fixation with 3 screws for a femoral neck fracture.4 Three of 5 measurements of parallelism and neck coverage were significantly improved by computer-assisted navigation; they included a larger relative neck area held by the screws (32% vs. 23%) and less deviation on the lateral projection for both the shaft (1.7° vs. 5.2°) and the fracture (1.7° vs. 5.5°) screw angles, all respectively. Slight improvements in anteroposterior screw angles (1.3° vs. 2.1° and 1.3° vs. 2.4°, respectively) were not statistically significant. There were 2 reoperations in the computer-assisted navigation group and 6 in the conventional group. Complications (collapse, subtrochanteric fracture, head penetration, osteonecrosis) were lower in the computer-assisted navigation group (3 vs. 11, respectively).

A retrospective comparative study by Swartman et al. (2021) investigated differences in conventional fluoroscopy-assisted percutaneous management (n = 13) of acetabular fractures to 3-dimensional (3D) -computer navigated management (n = 24).5 Both groups demonstrated significant reduction in fracture gaps and steps post-intervention. However, there were no significant differences between groups in outcomes related to fracture reduction or screw positions.

Section Summary: Computer-Assisted Navigation for Trauma or Fracture
There is limited literature on the use of computer-assisted navigation for trauma or fractures. Additional controlled studies that measure health outcomes are needed to evaluate this technology.

Computer-Assisted Navigation for Anterior Cruciate Ligament or Posterior Cruciate Ligament Reconstruction
Clinical Context and Therapy Purpose
The purpose of computer-assisted navigation is to provide a treatment option that is an alternative to or an improvement on existing therapies, such as conventional/manual alignment methods, in individuals who are undergoing ligament reconstruction.

The following PICO was used to select literature to inform this review.

Populations
The relevant population of interest is individuals who are undergoing ligament reconstruction.

Interventions
The therapy being considered is computer-assisted navigation. Computer-assisted navigation in orthopedic procedures describes the use of computer-enabled tracking systems to facilitate alignment in a variety of surgical procedures, including fixation of fractures, ligament reconstruction, osteotomy, tumor resection, preparation of the bone for joint arthroplasty, and verification of the intended implant placement.

Comparators
Comparators of interest include conventional/manual alignment methods. Treatment by means of conventional/manual alignment methods include medical reduction procedures.

Outcomes
The general outcomes of interest are symptoms, morbid events, and functional outcomes.

The existing literature evaluating computer-assisted navigation as a treatment for patients who are undergoing ligament reconstruction has varying lengths of follow-up. While studies described below all reported at least 1 outcome of interest, longer follow-up was necessary to fully observe outcomes. Therefore, 2 years of follow-up is considered necessary to demonstrate efficacy.

Study Selection Criteria
Methodologically credible studies were selected using the following principles:

  1. To assess efficacy outcomes, comparative controlled prospective trials were sought, with a preference for RCTs.

  2. In the absence of such trials, comparative observational studies were sought, with a preference for prospective studies.

  3. To assess long-term outcomes and adverse events, single-arm studies that capture longer periods of follow-up and/or larger populations were sought.

  4. Studies with duplicative or overlapping populations were excluded.

Review of Evidence
Systematic Reviews
Eggerding et al. (2014) published a Cochrane review that compared the effects of computer-assisted navigation with conventional operating techniques for anterior cruciate ligament or posterior cruciate ligament reconstruction.6 Five RCTs (N = 366 participants) on anterior cruciate ligament reconstruction were included in the updated review; no studies involved posterior cruciate ligament reconstruction. The quality of evidence ranged from moderate to very-low. Pooled data showed no statistically or clinically relevant differences in self-reported health outcomes (International Knee Documentation Committee subjective scores and Lysholm Knee Scale scores) at 2 or more years of follow-up. No significant differences were found for secondary outcomes, including knee stability, range of motion, and tunnel placement. Overall, there was insufficient evidence to advise for or against the use of computer-assisted navigation. Four of the 5 trials included in the Cochrane review are described next and in Tables 2 and 3.

Randomized Controlled Trials
Plaweski et al. (2006) reported on a trial that randomized 60 patients to manual or computer-assisted guidance for tunnel placement with follow-up at 1, 3, 6, 12, 18, and 24 months.7 There were no differences between groups in measurements of laxity. However, there was less variability in side-to-side anterior laxity in the navigated group (e.g., 97% were within 2 mm of laxity in the navigated group vs. 83% in the conventional group at an applied force of 150 N). There was a significant difference in the sagittal position of the tibial tunnel (distance from the Blumensaat line, 0.4 mm vs. -1.2 mm, respectively), suggesting possible impingement in extension for the conventional group. At the final follow-up (24 months), all knees had normal function, with no differences observed between groups.

Hart et al. (2008) compared biomechanical radiographic with functional results in 80 patients randomized to anterior cruciate ligament reconstruction using computer-assisted navigation (n = 40) or to the standard manual targeting technique (n = 40).8 The blinded evaluation found more exact bone tunnel placement with computer-assisted navigation, but no overall difference in biomechanical stability or function between groups.

Other studies have found no significant improvement in the accuracy of tunnel placement when using computer-assisted navigation. Meuffels et al. (2012) reported on a double-blind controlled trial that randomized 100 patients to conventional or computer-assisted surgery.9 Evaluation by 3-dimensional computed tomography (CT) found no significant difference between groups for the accuracy or the precision of the femoral and tibial tunnel placement.

Table 2. Summary of Characteristics of Key Randomized Controlled Trials Comparing Computer-Assisted Navigation With Manual Placement for Anterior or Posterior Cruciate Ligament Reconstruction

Study Countries Sites Dates Participants Interventions  
          Active Comparator
Plaweski et al. (2006)7 USA 1 Oct 2014 to Jan 2016 Patients (N = 60) undergoing ACL reconstruction. CAN (n = 30) Manual placement (n = 30)
Hart et al. (2008)8 Czech Republic 1 NR Patients (N = 80) undergoing ACL reconstruction for chronic rupture of the ACL; only chronic ACL-insufficiency knees were included in the study (>6 mo after injury). Other inclusion criteria were no other prior or simultaneous intra-articular surgical procedure, no cartilage degeneration of meniscal tear, and a normal contralateral knee. Ages ranged from 16 to 39 years with a mean of 29.4. Mean body weight was 74 kg. CAN (n = 40) Manual placement (n = 40)
Meuffels et al. (2012)9 Netherlands 1 Jan 2007 to Nov 2009 Patients (N = 100) ≥18 years of age and eligible for primary ACL reconstruction without additional PCL or lateral collateral ligament injury were included. CAN (n = 49) Conventional (n = 51)
Mauch et al. (2007)10 Germany 1 Dec 2003 to April 2004 Athletes aged 18 to 49 years (N = 53) with ACL rupture and no complex injuries of knee with additional injury of PCL, injury of posterior lateral complex, or third-degree injury of intra-articular ligament. CAN (n = 24) Manual placement (n = 29)

ACL: anterior cruciate ligament; CAN: computer-assisted navigation; NR: not reported; PCL: posterior cruciate ligament.

Table 3. Summary of Key Randomized Controlled Trials Comparing Computer-Assisted Navigation With Manual Placement for Anterior or Posterior Cruciate Ligament Reconstruction

Study IKDC Laxity < 2 mm Lachman Test (0) Lachman Test (2+) Placement of the Femoral Tunnel Tibial Tunnel Border
Plaweski et al. (2006)7            
CAN (n = 26 knees)         NR mean ATB, -0.2 (5 to +4)
Mean Level A laxity level (n = 26 knees) mean, 1.3 mm at 200 N; p = .49 96.7%; p = .295 23 (76.7) 1 (3.3)    
Manual (n = 22 knees)         NR mean ATB, 0.4 (0 to 3)
Mean Level A laxity level (n = 22 knees) mean, 1.5 mm at 200 N; p = .49 83%; p = .292 26 (87) 0 (0)    
Hart et al. (2008)8            
CAN (n = 40) Mean post-op Improvement: 76.5 points; SD, 10.3; p < .01 Mean difference in anterior laxity compared with contralateral (healthy) knee: 1.43 mm (range, 0 to 4 mm) 12 (30%) 14 (35%) Ideal a/t value: 24.8% Mean, 25.5% (SD, 1.63) Zone 2 location: 39 (97.5%)
Manual (n = 40) Mean post-op Improvement: 73.1 points; SD, 11.8; p<.01 Mean difference in anterior laxity compared with contralateral (healthy) knee: 1.24 mm (range, -2 to 5 mm) 18 (45%) 10 (25%) Ideal a/t value: 24.8% Mean, 27.% (SD, 2.76) Zone 2 location: 38 (95.0%)
Meuffels et al. (2012)9            
CAN (n = 49) NR NR NR NR Mean 39% of the proximal distance on the intracondylar axis Distance from most medial edge: 42.7% ±3.6%
Manual (n = 51) NR NR NR NR Mean 39.7% of the proximal distance on the intracondylar axis Distance from most medial edge: 42.6% ±5.7%
Mauch et al. (2007)10            
CAN (n = 24) NR NR NR NR NR 21.2 mm (32.2%)
Manual (n = 29) NR NR NR NR NR 19.4 mm (29.7%)
p value NR NR NR NR NR .18

a/t value: ratio identifies anterior-posterior femoral tunnel placement; ATB: anterior tension band plate; CAN: computer-assisted navigation; IKDC: International Knee Documentation Committee; NR: not reported; Post-op: postoperative; SD: standard deviation.

The purpose of the limitations tables (see Tables 4 and 5) is to display notable limitations identified in each study. This information is synthesized as a summary of the body of evidence following each table and provides the conclusions on the sufficiency of evidence supporting the position statement.

Table 4. Summary of Study Relevance Limitations in Key Randomized Controlled Trials Comparing Computer-Assisted Navigation With Manual Placement

Study Populationa Interventionb Comparatorc Outcomesd Follow-Upe
Plaweski et al. (2006)7 3. Limited demographic information provided.        
Hart et al. (2008)8 3. The study setting and source of study participants are missing (as is the referral pattern)—this could create referral-filter bias.        
Meuffels et al. (2012)9 3. Study population is incompletely characterized. 2.Inconsistent fidelity of intervention protocol: There is a lack of consistency as to the best method for performing the intervention.      
Mauch et al. (2007)10 1, 4.Intended use population is unclear. Limited to athletes.     5, 6. Clinically significant difference not prespecified or mentioned. 1,2. Follow-up was 4 days, not long enough to determine intermediate- or long-term outcomes.

The study limitations stated in this table are those notable in the current review; this is not a comprehensive gaps assessment.
a Population key: 1. Intended use population unclear; 2. Study population is unclear; 3. Study population not representative of intended use; 4. Enrolled populations do not reflect relevant diversity; 5. Other.
b Intervention key: 1. Not clearly defined; 2. Version used unclear; 3. Delivery not similar intensity as comparator; 4. Not the intervention of interest.
c Comparator key: 1. Not clearly defined; 2. Not standard or optimal; 3. Delivery not similar intensity as intervention; 4. Not delivered effectively.
d Outcomes key: 1. Key health outcomes not addressed; 2. Physiologic measures, not validated surrogates; 3. No CONSORT reporting of harms; 4. Not established and validated measurements; 5. Clinical significant difference not prespecified; 6. Clinical significant difference not supported.
e Follow-Up key: 1. Not sufficient duration for benefit; 2. Not sufficient duration for harms.

Table 5. Summary of Design and Conduct Limitations in Key Randomized Controlled Trials Comparing Computer-Assisted Navigation With Manual Placement

  Allocationa Blindingb Selective Reportingc Data Completenessd Powere Statisticalf
Plaweski et al. (2006)7   1. Unclear whether patients were blinded.       3. Confidence intervals not reported.
4. Comparison of treatment effect not provided.
Hart et al. (2008)8 3. Randomization techniques are not described in any manner within the text.       1. Power calculations not reported. 3. Confidence intervals not reported.
Meuffels et al. (2012)9            
Mauch et al. (2007)10 4. Drawing lots is a weak method of allocation. 1, 2, 3. Blinding is not mentioned at all.     1. Power calculations not reported. 3. Confidence intervals not reported.

The study limitations stated in this table are those notable in the current review; this is not a comprehensive gaps assessment.
a Allocation key: 1. Participants not randomly allocated; 2. Allocation not concealed; 3. Allocation concealment unclear; 4. Inadequate control for selection bias.
b Blinding key: 1. Not blinded to treatment assignment; 2. Not blinded outcome assessment; 3. Outcome assessed by treating physician.
c Selective Reporting key: 1. Not registered; 2. Evidence of selective reporting; 3. Evidence of selective publication.
d Data Completeness key: 1. High loss to follow-up or missing data; 2. Inadequate handling of missing data; 3. High number of crossovers; 4. Inadequate handling of crossovers; 5. Inappropriate exclusions; 6. Not intent to treat analysis (per protocol for noninferiority trials).
e Power key: 1. Power calculations not reported; 2. Power not calculated for primary outcome; 3. Power not based on clinically important difference.
f Statistical key: 1. Analysis is not appropriate for outcome type: (a) continuous; (b) binary; (c) time to event; 2. Analysis is not appropriate for multiple observations per patient; 3. Confidence intervals and/or p values not reported; 4. Comparative treatment effects not calculated.

Section Summary: Computer-Assisted Navigation for Anterior Cruciate Ligament or Posterior Cruciate Ligament Reconstruction
The evidence on computer-assisted navigation for anterior cruciate ligament or posterior cruciate ligament reconstruction includes a systematic review of 5 RCTs. These RCTs, of moderate- to low-quality, did not consistently demonstrate more accurate tunnel placement with computer-assisted navigation. No studies have shown an improvement in functional outcomes or need for revision when computer-assisted navigation is used for anterior cruciate ligament or posterior cruciate ligament reconstruction.

Computer-Assisted Navigation for Total Hip Arthroplasty and Periacetabular Osteotomy
Clinical Context and Therapy Purpose
The purpose of computer-assisted navigation is to provide a treatment option that is an alternative to or an improvement on existing therapies, such as conventional/manual alignment methods, in individuals who are undergoing THA and periacetabular osteotomy.

The following PICO was used to select literature to inform this review.

Populations
The relevant population of interest is individuals who are undergoing THA and periacetabular osteotomy.

Interventions
The therapy being considered is computer-assisted navigation. Computer-assisted navigation in orthopedic procedures describes the use of computer-enabled tracking systems to facilitate alignment in a variety of surgical procedures, including fixation of fractures, ligament reconstruction, osteotomy, tumor resection, preparation of the bone for joint arthroplasty, and verification of the intended implant placement.

Comparators
Comparators of interest include conventional/manual alignment methods. Treatment by means of conventional/manual alignment methods include medical reduction procedures.

Outcomes
The general outcomes of interest are symptoms, morbid events, and functional outcomes.

The existing literature evaluating computer-assisted navigation as a treatment for patients who are undergoing THA and periacetabular osteotomy has varying lengths of follow-up, ranging from 6 to 40 months. While studies described below all reported at least 1 outcome of interest, longer follow-up was necessary to fully observe outcomes.

Study Selection Criteria
Methodologically credible studies were selected using the following principles:

  1. To assess efficacy outcomes, comparative controlled prospective trials were sought, with a preference for RCTs.

  2. In the absence of such trials, comparative observational studies were sought, with a preference for prospective studies.

  3. To assess long-term outcomes and adverse events, single-arm studies that capture longer periods of follow-up and/or larger populations were sought.

  4. Studies with duplicative or overlapping populations were excluded.

Review of Evidence
Systematic Reviews
Kunze et al. (2023) published a systematic review comparing surgical time, short-term adverse events, and implant placement accuracy between manual, robotic-assisted, and computer-navigated THA.11 Seven RCTs were identified comparing computer-assisted navigation and manual THAs. Table 6 outlines the studies included comparing computer-assisted THA and manual THA. Characteristics and results specific to computer-assisted navigation are shown in Tables 7 and 8, respectively. In brief, manual THA resulted in significantly shorter surgical times and a similar incidence of complications and revisions compared to computer-assisted THA. However, computer-assisted navigation THA led to increased precision in the placement of acetabular implants. These results are limited by a lack of recent RCTs, inability to conduct meta-analysis of patient-reported outcome measures, and use of the Lewinnek safe zone as a benchmark for proper acetabular implant positioning, which may not be appropriate in all patients. Additionally, there were a variety of computer-assisted navigation systems used across RCTs, limiting conclusions regarding any particular system.

Table 6. Comparison of RCTs Included in Systematic Reviews and Meta-Analyses for Computer-Assisted Navigation for THA

Study Kunze et al. (2022)a11,
Leenders et al. (2002)
Gurgel et al. (2014)
Lass et al. (2014)
Renkawitz et al. (2015)
Parratte et al. (2016)
Weber et al. (2016)
Verdier et al. (2016)

RCT: randomzied controlled trial; THA: total hip arthroplasty.
a Only articles comparing computer navigation and manual total hip arthroplasty procedures are included in table.

Table 7. Systematic Reviews and Meta-Analyses for Computer-Assisted Navigation for THA: Characteristics

Study Dates Trials Participants N (Range) Design Duration, mean
Kunze et al. (2022)11 2008 – 2019 7 Computer-assisted navigation THA compared to manual THA with at least 1-year follow-up. 598 (40 to 135) RCT 4.3 yrs (range, 1 to 14.2 yrs)a

a Mean duration includes all studies included in systematic review, including robotic-assisted THA studies.
RCT: randomized controlled trial; THA: total hip arthroplasty 

Table 8. Systematic Reviews and Meta-Analyses for Computer-Assisted Navigation for THA: Results

Study Operation length, mins All-cause complications All-cause revisions Acetabular implant positioning (% of acetabular cups placed in safe zone)
Kunze et al. (2022)11
Total N 373 (3 studies) NR (11 studies) 598 (7 studies) 178 (3 studies)
Manual THA mean, 86.6 mins Total = 38 (6.6%) Total = 2 46/89 (52%)
Computer-assisted THA mean, 95.7 mins Total = 5 (1.7%) Total = 3 70/89 (79%)
Pooled effect (95% CI) SMD, 8.55 (3.49 to 13.60) OR, 0.83 (0.23 to 2.99) OR, 1.15 (0.30 to 4.42) ES, 0.79 (0.69 to 0.86)
p-value < .001 .781 .840 .02
I2 (p) -- -- -- 0% (.29)

CI: confidence interval; ES: effect size; NR: not reported; OR: odds ratio; SMD: standard mean difference; THA: total hip arthroplasty.

Nonrandomized Studies
Manzotti et al. (2011) compared leg length restoration in a matched-pair study.12 Forty-eight patients undergoing THA with computer-assisted navigation were compared with patients who were matched for age, sex, arthritis level, preoperative diagnosis, and preoperative leg length discrepancy and underwent conventional freehand THA using the same implant in the same period. The mean preoperative leg length discrepancy was 12.17 mm in the computer-assisted navigation group and 11.94 mm in the standard group. Surgical time was increased by 16 minutes in the computer-assisted navigation group (89 minutes vs. 73 minutes). There was a significant decrease in both the mean postoperative leg length discrepancy (5.06 mm vs. 7.65 mm) and the number of cases with a leg length discrepancy of 10 mm or more (5 patients vs. 13 patients), all respectively. Outcomes at 40-month follow-up (range, 7 to 77 months) did not differ significantly for the Harris Hip Score (88.87 vs. 89.73) or the 100-point normalized Western Ontario and McMaster Universities Arthritis Index score (9.33 vs. 13.21; p = .050), all respectively. Longer follow-up with a larger number of subjects is needed to determine whether computer-assisted navigation influences clinical outcomes.

Minimally Invasive Total Hip Arthoplasty
Systematic Reviews
It has been proposed that computer-assisted navigation might overcome the difficulties of reduced visibility of the surgical area associated with minimally invasive procedures. Ulrich et al. (2007) summarized study results that compared outcomes from minimally invasive THA using computer-assisted navigation with standard THA.13 Seventeen studies were described in this evidence-based review, including 9 prospective comparisons, 7 retrospective comparisons, and 1 large (N = 100) case series. Reviewers concluded that alignment with minimally invasive computer-assisted navigation appears to be at least as good as standard THA, although the more consistent alignment must be balanced against the expense of the computer systems and increased surgical time.

Randomized Controlled Trials
Reininga et al. (2013) reported short-term outcomes of minimally invasive THA approach with computer-assisted navigation (n = 35) compared with conventional posterolateral THA (n = 40).14 This randomized comparison found no group differences in the recovery of gait at up to 6 months postsurgery.

Periacetabular Osteotomy
Randomized Controlled Trials
Hsieh et al. (2006) reported on 36 patients with symptomatic adult dysplastic hip who were randomized to CT-based navigation or the conventional technique for periacetabular osteotomy.15 An average of 0.6 intraoperative radiographs were taken in the navigated group compared with 4.4 in the conventional group, resulting in a total surgical time that was 21 minutes shorter for computer-assisted navigation. There were no differences between groups for correction in femoral head coverage or functional outcomes (pain, walking, range of motion) at 24 months.

Total Hip Resurfacing
Randomized Controlled Trials
Stiehler et al. (2013) reported on short-term radiographic and functional outcomes from a randomized comparative trial of total hip resurfacing using computer-assisted navigation and conventional total hip resurfacing in 75 patients.16 For most of the radiographic measures, there were no significant differences between the computer-assisted navigation and conventional total hip resurfacing groups. There were fewer outliers (≥ 5°) for the femoral component with computer-assisted navigation (11%) compared with conventional placement (32%). At 6-month follow-up, there were no differences between groups in the final Western Ontario and McMaster Universities score or Harris Hip Score. The computer-assisted navigation group did show a greater percentage improvement in the Western Ontario and McMaster Universities scores and Harris Hip Score due to differences between groups at baseline.

Section Summary: Computer-Assisted Navigation for Total Hip Arthroplasty and Periacetabular Osteotomy
Relatively few RCTs have evaluated computer-assisted navigation for hip procedures. Although there was an early interest in this technology, no recent RCTs have been identified. There is inconsistent evidence from systematic reviews of these small trials on whether computer-assisted navigation improves alignment with conventional or minimally invasive THA. One RCT found improved alignment when computer-assisted navigation was used for hip resurfacing, but there was little evidence of improved outcomes at short-term follow-up. Overall, improved health outcomes have not been demonstrated with computer-assisted navigation for any hip procedures.

Computer-Assisted Navigation for Total Knee Arthroplasty
Clinical Context and Therapy Purpose
The purpose of computer-assisted navigation is to provide a treatment option that is an alternative to or an improvement on existing therapies, such as conventional/manual alignment methods, in individuals who are undergoing TKA.

The following PICO was used to select literature to inform this review.

Populations
The relevant population of interest is individuals who are undergoing TKA.

Interventions
The therapy being considered is computer-assisted navigation. Computer-assisted navigation in orthopedic procedures describes the use of computer-enabled tracking systems to facilitate alignment in a variety of surgical procedures, including fixation of fractures, ligament reconstruction, osteotomy, tumor resection, preparation of the bone for joint arthroplasty, and verification of the intended implant placement.

Comparators
Comparators of interest include conventional/manual alignment methods. Treatment by means of conventional/manual alignment methods include medical reduction procedures.

Outcomes
The general outcomes of interest are symptoms, morbid events, and functional outcomes.

The existing literature evaluating computer-assisted navigation as a treatment for patients who are undergoing TKA has varying lengths of follow-up, ranging from 1 to 8 years. While studies described below all reported at least 1 outcome of interest, longer follow-up was necessary to fully observe outcomes.

Alignment of a knee prosthesis can be measured along several different axes, including the mechanical axis, and the frontal and sagittal axes of both the femur and tibia.

Study Selection Criteria
Methodologically credible studies were selected using the following principles:

  1. To assess efficacy outcomes, comparative controlled prospective trials were sought, with a preference for RCTs.

  2. In the absence of such trials, comparative observational studies were sought, with a preference for prospective studies.

  3. To assess long-term outcomes and adverse events, single-arm studies that capture longer periods of follow-up and/or larger populations were sought.

  4. Studies with duplicative or overlapping populations were excluded.

Review of Evidence
Systematic Reviews
A systematic review conducted by Xie et al. (2012) included 21 randomized trials (N = 2,658 patients) that reported on clinical outcomes with or without the use of computer-assisted navigation (Table 9).17 Most trials included in the review had short-term follow-up. Surgical time was significantly increased with computer-assisted navigation for TKA, but there was no significant difference between approaches in total operative blood loss, the Knee Society Score, or range of motion (Table 10).

Rebal et al. (2014) conducted a meta-analysis of 20 RCTs (N = 1,713 knees) that compared imageless navigation technology with conventional manual guides (Table 9).18 The majority of included studies had a low risk of bias. The improvement in Knee Society Score was statistically superior in the computer-assisted navigation group at 3 months and 12 to 32 months (Table 10). However, these improvements did not achieve the minimal clinically significant difference, defined as a change of 34.5 points.

Table 9. Characteristics of Systematic Reviews and Meta-Analyses Investigating Total Knee Arthroplasty

Study Dates Trials Participants N (Range) Design Duration
Xie et al. (2012)17 PubMed and EMBASE through August 2011 21 Included 2,658 patients. Among these, 1,376 were randomly allocated to the computer-assisted TKA group and 1,282 to the conventional group 2,658 (25 to 120) RCT NR
Rebal et al. (2014)18 PubMed, EMBASE, Scopus, and CENTRAL through December 2012 20 Included a combined 869 knees in the computer-assisted groups, and 844 knees in the control groups for a total of 1,713 knees analyzed 1,713 knees (46 to 166) RCT 3 mos and 12 to 32 mos

NR: not reported; RCT: randomized controlled trial; TKA: total knee arthroplasty.

Table 10. Results of Systematic Reviews and Meta-Analyses Investigating Total Knee Arthroplasty

Study Knee Society Score Operative Time
Xie et al. (2012)17
Mean standard difference 4.47 14.68
95% CI -1.05 to 9.99 11.74 to 17.62
P-value .36 < .0001
  CAN Conventional CAN (min) Conventional (min)
  3 Months 12 to 32 Months 3 Months 12 to 32 Months    
Rebal et al. (2014)18
Mean 68.5 53.1 58.1 45.8 101.6 83.3
95% CI     1.13 to 19.78 2.87 to 11.90   11.84 to 24.60
P-value     .03 < .01   < .01

CAN: computer-assisted navigation; CI: confidence interval.

Effect of Computer-Assisted Navigation on Mid- to Long-Term Outcomes
Randomized Controlled Trials

RCTs comparing outcomes at 4 to 12 years follow-up generally have shown a reduction in the number of outliers with computer-assisted navigation, but little to no functional difference between the computer-assisted navigation and conventional TKA groups.

Three trials comparing computer-assisted navigation and conventional surgery reported on outcomes at 4 to 5 years follow-up (N = 67 to 107). Blakeney et al. (2014) reporting 46-month follow-up for 107 patients 19 found a trend toward higher scores on the Oxford Knee Questionnaire with computer-assisted navigation, with a mean score of 40.6 for the computer-assisted navigation group compared with 37.6 and 36.8 in extramedullary and intramedullary control groups, respectively. There were no significant differences in the 12-Item Short-Form Health Survey Physical Component or Mental Component Summary scores. The trial was underpowered, and the clinical significance of this trend for the Oxford Knee Questionnaire is unclear. Lutzner et al. (2013), reporting on 5-year follow-up for 67 of 80 patients20 found a significant decrease in the number of outliers with computer-assisted navigation (3 vs. 9; p = .048) but no significant differences between groups on the Knee Society Score or Euroquol quality of life questionnaire. At 10-years post surgery, a follow-up study (Beyer et al. 2021) of 50 patients originally included in the Lutzner et al. 2013 study showed no significant differences in the number of outliers between groups, patient-reported outcomes from the Knee Society Score of Euroquol quality of life questionnaire, and no differences in revision risk.21 Cip et al. (2014) found a significant decrease in malalignment with computer-assisted navigation, but no significant differences in implant survival or consistent differences in clinical outcome measures between the navigated (n = 100) and conventional (n = 100) total knee arthroplasty groups at minimum 5-year follow-up.22

Four additional trials comparing computer-assisted and conventional surgery reported outcomes after 8 to 12 years follow-up (N = 60 to 200). Hsu et al. (2019) reported similar clinical and functional outcomes with the 2 procedures after a mean 8.1-year follow-up, although computer-assisted navigation achieved better radiographic alignment and fewer outliers.23 They suggested that TKA with computer-assisted navigation may not provide an advantage to the typical osteoarthritis patient, but it may benefit certain patients, such as those with severe deformity of the knee joint, extra-articular deformities, and severe femoral bowing. The study was limited by its solely Asian patient population, single-center, and small sample size. Song et al. (2016) also reported on a reduction in the number of outliers with computer-assisted navigation (7.3% vs. 20%; p = .006), with no significant differences in clinical outcomes at 8-year follow-up.24 The trial, which assessed 80 patients (88 knees) was powered to detect a 3-point difference in Knee Society Score results. Cip et al. (2018) published the results of a prospective randomized trial (N = 200) comparing conventional TKA with computer-assisted TKA with a mean follow-up of 12 years postoperatively.25 The trial was aimed at determining the long-term outcomes of computer-assisted navigation for TKA as a tool to expedite long-term survival based on improved postoperative implantation. The follow-up rate was 75%. No difference in long-term TKA survival was found between the conventional group (91.5%) and the computer-assisted navigation group (98.2%) at 12 years (p = .181). In a single-blinded, prospective RCT, Farhan-Alanie et al. (2023) compared conventional TKA (n = 98) with computer-assisted TKA (n = 101), with a mean follow-up of 10 years.26 Over the 10-year period, there were 23 deaths (22.8%) in the computer-assisted group and 30 deaths (30.6%) in the conventional cohort. At the 10-year follow-up, the authors found no difference in revision rates (4.0% computer-navigation vs 6.1% conventional; p = .429) or clinical outcomes, including Oxford Knee Scores, American Knee Society Scores, or mental and physical scores on the 36-item Short-Form survey between groups.

Comparative Studies
Results from observational studies have generally been consistent with the systematic reviews and RCTs.27,28,29,30,31,32 The longest of these observational studies, conducted by Dyrhovden et al. (2016), assessed survivorship and the relative risk of revision at 8-year follow-up for 23,684 cases from the Norwegian Arthroplasty Register for patients treated with computer-assisted navigation or conventional surgery.31 Overall prosthesis survival and risk of revision were similar for both groups, although revisions due to malalignment were reduced with computer-assisted navigation (relative risk, 0.5; 95% confidence interval [CI], 0.3 to 0.9; p = .02). There were no significant differences between groups for other reasons for revision (e.g., aseptic loosening, instability, periprosthetic fracture, decreased range of motion). At 8 years, the survival rate was 94.8% (95% CI, 93.8% to 95.8%) in the computer-assisted navigation group and 94.9% (95% CI, 94.5% to 95.3%) for conventional surgery.

In the largest observational study, Antonios et al. (2020) compared Medicare data from 75,709 patients who underwent a computer navigated TKA with a matched cohort of 75,676 Medicare patients who underwent conventional TKA.32 There was no statistically significant difference in 5-year event-free survival in all-cause revisions between groups (95.1% vs. 94.7%; p = .06) However, there was a small difference in revisions due to mechanical complications (96.1% vs. 95.7%; p = .02) but not in revisions due to periprosthetic joint infection (97.9% vs. 97.9%; p = .30)

A retrospective comparison cohort study by Webb et al. (2021) compared conventional TKA cases (n = 219,880) to computer navigated TKA cases (n = 5,243) that occurred from 2008 through 2016 and were documented in the American College of Surgeons National Surgical Quality Improvement Program database.33 In univariate analysis of unmatched cohorts, rates of composite serious morbidities and death or serious morbidity were significantly higher in the conventional TKA group than the computer navigated group (8.47% vs. 7.54%; p = .016). In multivariable regression analysis, computer navigated TKA was found to be significantly associated with lower rates of serious morbidity (odds ratio [OR], 0.83; p = .001), death or serious morbidity (OR, 0.82; p < .001) and length of stay (OR, 0.86; p = .024). Propensity score matching identified 4,811 case pairs of conventional versus computer navigated TKA. Propensity-matched analyses demonstrated no significant difference in mortality, length of operation time, length of stay, or rates of reoperation or readmission. The composite rate of complications was 18% less in the computer navigated group compared to the conventional TKA group (p = .009).

Section Summary: Computer-Assisted Navigation for Total Knee Arthroplasty
Based on systematic reviews, a large number of RCTs have assessed outcomes for TKA using computer-assisted navigation or conventional TKA without computer-assisted navigation. Results are consistent in showing reductions in the proportion of outliers greater than 3° in alignment. Results from individual RCTs and cohort studies up to 12 years postoperatively have not shown that these differences in alignment lead to improved patient outcomes.

Computer-Assisted Navigation for Spine Surgery
Clinical Context and Therapy Purpose

The purpose of computer-assisted navigation is to provide a treatment option that is an alternative to or an improvement on existing therapies, such as conventional/manual methods, in individuals who are undergoing spine surgery, particularly spinal fusion surgery for radiculopathy and correction of spinal deformities (e.g., scoliosis). Spinal fusion may include the use of pedicle screws. Pedicle screws are a type of bone screw that, along with rods, is used to secure the vertebrae in a fixed position following fusion. Pedicle screws may be removed once healing has occurred, or they can be left in place. Pedicle screw placement accuracy is critical, as misplacement can cause a variety of complications, including pain and weakness or perforation leading to damage to surrounding nerves, soft tissues and bones.

The following PICO was used to select literature to inform this review.

Populations
The relevant population of interest is individuals who are undergoing spine surgery. This can include patients undergoing cervical, thoracic or lumbar pedicle screw placement in association with spinal fusion surgery, due to trauma or for correction of spinal deformities, or patients undergoing spinal tumor resection.

Interventions
The therapy being considered is computer-assisted navigation. Computer-assisted navigation in orthopedic procedures describes the use of computer-enabled tracking systems to facilitate alignment in a variety of surgical procedures, including tumor resection and pedicle screw placement.

Comparators
Comparators of interest include conventional/manual surgical methods, such as fluoroscopically-guided freehand surgery.

Outcomes
The general outcomes of interest are symptoms, morbid events, and functional outcomes. Many studies report pedicle screw perforation (breach or encroachment into surrounding tissues, bones or organs) as a measure of procedural success. However, because not all screw perforations lead to symptoms or morbid events, revision surgeries would be a more relevant measure of clinical outcomes.

Study Selection Criteria
Methodologically credible studies were selected using the following principles:

  • To assess efficacy outcomes, comparative controlled prospective trials were sought, with a preference for RCTs.
  • In the absence of such trials, comparative observational studies were sought, with a preference for prospective studies.
  • To assess long-term outcomes and adverse events, single-arm studies that capture longer periods of follow-up and/or larger populations were sought.
  • Studies with duplicative or overlapping populations were excluded.

Review of Evidence
Pedicle Screw Insertion For Spinal Fusion or Deformity Correction
Systematic Reviews

Numerous systematic reviews of mostly retrospective observational studies have assessed pedicle screw placement using computer-assisted navigation; however, evidence on health outcomes from the reviews is limited.34,35,36,37 In a 2018 review conducted by Staartjes et al., comparing computer-assisted navigation (n = 1,779 pedicle screws) and freehand placement (n = 1,809 pedicle screws) and the need for intraoperative revision, there was a nonsignificant trend favoring freehand placement based on an imprecise risk estimate (OR, 1.46 ; 95% CI, 0.30 to 7.17; I2 = 88%).36 The same review found the need for postoperative revision was significantly lower with computer-assisted navigation versus freehand placement (OR, 0.31; 95% CI, 0.21 to 0.46; I2 = 0%). Another review, conducted by Perdomo-Pantoja et al. (2019)37 reported similar rates of screw placement accuracy with computer-assisted navigation (95.5%) and other placement methods (90.5% to 93.1%). Consistent with the RCT evidence discussed below, an older review by Shin et al. (2012)35, found a lower risk of pedicle screw perforation with computer-assisted navigation (6%; 287/4814) versus conventional, non-navigated screw placement (15%; 556/3725; risk ratio [RR], 0.39; 95% CI, 0.31 to 0.49; I2 = 49%). The review found no difference between navigated and non-navigated screw placement on operative time (-3.06 minutes; 95% CI, -35.60 to 29.48), estimated blood loss (-91.6 mL ; 95% CI, -185.95 to 3.24), or overall revision rate per screw insertion (1.44% vs. 2.03%; p = .11).

Randomized Controlled Trials
Three RCTs have compared pedicle screw insertion by computer-assisted navigation with conventional surgical techniques (Table 11). None of the trials reported health outcomes or post-surgical follow-up (Table 12). In the largest RCT, conducted by Laine et al. (2000),38 computer-assisted navigation was associated with longer surgical time than conventional surgery and fewer instances of pedicle screw perforation. A second, smaller RCT conducted by Rajasekaran et al. (2007)39 found pedicle screw placement using computer-assisted navigation associated with shorter placement time and a lower rate of pedicle perforation relative to fluoroscopically-guided placement. The third trial (N = 21) compared the risk of patient and surgical team radiation exposure with pedicle screw placement using computer-assisted navigation with freehand, fluoroscopically-guided screw placement.40 The trial found significantly higher radiation exposure to the surgical team during freehand screw insertion (p < .01) with no difference between intervention groups and cumulative patient radiation dose. Tables 13 and 14 summarize key study relevance and design and conduct limitations.

Table 11. Summary of Key Randomized Controlled Trial Characteristics

Study; Trial Countries Sites Dates Participants Interventions
          Active Comparator
Laine et al. (2000)38 Finland 1 1998 – 1999 Patients undergoing thoracolumbar or lumbosacral fusion Pedicle screw placement using computer-assisted navigation; n = 41 Conventional pedicle screw placement; n = 50
Rajasekaran et al. (2007)39 India 1 Not reported Patients with scoliosis (40°to 80°) or kyphosis (≤ 90°) undergoing spinal deformity correction of the thoracic spine Pedicle screw placement using computer-assisted navigation; n = 17 Pedicle screw placement using fluoroscopic guidance; n = 16
Villard et al. (2014)40 Germany 1 Not reported Patients undergoing lower thoracic and lumbar posterior transforaminal interbody fusion Pedicle screw placement using computer-assisted navigation; n = 10 Pedicle screw placement using fluoroscopic guidance as needed; n = 11

Table 12. Summary of Key Randomized Controlled Trial Results

Study; Trial Mean Insertion Time Pedicle Screw Perforation Radiation Exposure
Laine et al. (2000)38 n = 91 (496 screws) n = 91 (496 screws) --
Computer-assisted navigation 40.0 (SD 16) minutes total insertion time 4.6% (10/219) Not reported
Conventional placement 28.7 (SD 17) minutes total insertion time 13.4% (37/277) Not reported
p value p = .001 p = .006 --
Rajasekaran et al. (2007)39 n = 33 (478 screws) n = 33 (478 screws) --
Computer-assisted navigation 2.4 (SD 0.7) minutes per screw 2.1% (5/242) Not reported
Conventional placement 4.6 (SD 1.1) minutes per screw 22.9% (54/236) Not reported
p value p < .001 p < .001 --
Villard et al. (2014)40 -- -- n = 21 patients
Computer-assisted navigation Not reported Not reported 888 (SD 449) cGy•cm2
Conventional placement Not reported Not reported 1884 (SD 881) cGy•cm2
p value -- -- p = .73

SD: standard deviation.

Table 13. Study Relevance Limitations

Study Populationa Interventionb Comparatorc Outcomesd Duration of Follow-upe
Laine et al. (2000)38       1, 2. The study reported on pedicle screw perforation but not clinical outcomes. 1, 2. Follow-up was insufficient to assess benefits and harms
Rajasekaran et al. (2007)39       1, 2. The study reported on pedicle screw perforation but not clinical outcomes. 1, 2. Follow-up was insufficient to assess benefits and harms
Villard et al. (2014)40       1, 2. The study reported on radiation exposure but not clinical outcomes. 1, 2. Follow-up was insufficient to assess benefits and harms

The study limitations stated in this table are those notable in the current review; this is not a comprehensive gaps assessment.
a Population key: 1. Intended use population unclear;2. Study population is unclear; 3. Study population not representative of intended use; 4. Enrolled populations do not reflect relevant diversity; 5. Other.
b Intervention key: 1. Not clearly defined; 2. Version used unclear; 3. Delivery not similar intensity as comparator; 4. Not the intervention of interest.
c Comparator key: 1. Not clearly defined; 2. Not standard or optimal; 3. Delivery not similar intensity as intervention; 4. Not delivered effectively.
d Outcomes key: 1. Key health outcomes not addressed; 2. Physiologic measures, not validated surrogates; 3. No CONSORT reporting of harms; 4. Not establish and validated measurements; 5. Clinical significant difference not prespecified; 6. Clinical significant difference not supported.
e Follow-Up key: 1. Not sufficient duration for benefit; 2. Not sufficient duration for harms.

Table 14. Study Design and Conduct Limitations

Study Allocationa Blindingb Selective Reportingc Data Completenessd Powere Statisticalf
Laine et al. (2000)38         1. Power calculations not reported  
Rajasekaran et al. (2007)39         1. Power calculations not reported  
Villard et al. (2014)40 3. Allocation concealment is unclear 1, 2. Not blinded to treatment assignment or outcome assessment        

The study limitations stated in this table are those notable in the current review; this is not a comprehensive gaps assessment.
a Allocation key: 1. Participants not randomly allocated; 2. Allocation not concealed; 3. Allocation concealment unclear; 4. Inadequate control for selection bias.
b Blinding key: 1. Not blinded to treatment assignment; 2. Not blinded outcome assessment; 3. Outcome assessed by treating physician.
c Selective Reporting key: 1. Not registered; 2. Evidence of selective reporting; 3. Evidence of selective publication.
d Data Completeness key: 1. High loss to follow-up or missing data; 2. Inadequate handling of missing data; 3. High number of crossovers; 4. Inadequate handling of crossovers; 5. Inappropriate exclusions; 6. Not intent to treat analysis (per protocol for noninferiority trials).
e Power key: 1. Power calculations not reported; 2. Power not calculated for primary outcome; 3. Power not based on clinically important difference.
f Statistical key: 1. Analysis is not appropriate for outcome type: (a) continuous; (b) binary; (c) time to event; 2. Analysis is not appropriate for multiple observations per patient; 3. Confidence intervals and/or p values not reported; 4. Comparative treatment effects not calculated.

Other Indications
The use of computer-assisted navigation for the treatment of spinal tumors has been reported in uncontrolled case series and case reports.41,42,43 Although the use of computer-assisted navigation appears safe for tumor resection based on these reports, evidence is too limited to draw any conclusions regarding the effect of computer-assisted navigation on health outcomes.

Section Summary — Computer-Assisted Navigation for Spine Surgery
Evidence from RCTs and larger observational studies found that computer-assisted navigation was associated with lower rates of pedicle screw perforation compared with other surgical placement methods. Evidence on clinical outcomes, including long-term health outcomes, is lacking.

The purpose of the following information is to provide reference material. Inclusion does not imply endorsement or alignment with the evidence review conclusions.

Clinical Input From Physician Specialty Societies and Academic Medical Centers
While the various physician specialty societies and academic medical centers may collaborate with and make recommendations during this process, through the provision of appropriate reviewers, input received does not represent an endorsement or position statement by the physician specialty societies or academic medical centers, unless otherwise noted.

2011 Input
In response to requests, input was received from 3 academic medical centers while this policy was under review in 2011. Input was mixed on whether computer-assisted navigation is considered investigational. One reviewer provided additional references on high tibial osteotomy and pelvic tumor resection.

Practice Guidelines and Position Statements
Guidelines or position statements will be considered for inclusion in Supplemental Information if they were issued by, or jointly by, a U.S. professional society, an international society with U.S. representation, or National Institute for Health and Care Excellence (NICE). Priority will be given to guidelines that are informed by a systematic review, include strength of evidence ratings, and include a description of management of conflict of interest.

American Academy of Orthopedic Surgeons
The American Academy of Orthopedic Surgeons updated guidelines in 2022 on surgical management of osteoarthritis of the knee.44, Related to computer-assisted surgical navigation, the guidelines state there is no difference in outcomes, function, or pain between computer-navigation and conventional techniques for total knee arthroplasty (strength of evidence: strong; strength of recommendation: moderate), and make no specific recommendation related to its use. The guidelines note that the advantages of surgical navigation remain unclear.

U.S. Preventive Services Task Force Recommendations
Not applicable

Ongoing and Unpublished Clinical Trials
Some currently unpublished trials that might influence this review are listed in Table 15.

Table 15. Summary of Key Trials

NCT No. Trial Name Planned Enrollment Completion Date
Ongoing      
NCT03628378 Outcomes in Free-hand Versus Sensor-guided Balancing in Total Knee Arthroplasty: a Randomized Controlled Trial 130 Dec 2022
NCT02717299a Making Sense Out of Total Knee Sensor Assisted Technology: A Randomized Control Trial 78 Apr 2021 (recruitment status unknown)
NCT04960345 Comparison of Accuracy and Clinical Outcomes Between Brainlab Knee 3 Computer-assisted Navigation Systems and Conventional Instruments in TKA: a Prospective Cohort Study 188 Dec 2023
Unpublished      
NCT01469299a Prospective Study Measuring Clinical Outcomes of Knee Arthroplasty Using the VERASENSE™ Knee System 285 Dec 2016
(updated 01/11/17)
NCT03668756 Comparison of Computer-Assisted Navigation and Conventional Instrumentation for Bilateral Total Knee Arthroplasty: The Functional Outcome of Mid-Term Follow-up Study 56 Aug 2018
NCT02190435a Computer-Assisted Navigation for Intramedullary Nail Fixation of Intertrochanteric Femur Fractures 65 Jan 2016
NCT03817632a Prospective, Multicenter, Observational, Comparative Clinical Trial on the Equivalence of Two Different OrthoPilot® Navigation System Generations Applied for Computer-assisted Total Knee Arthroplasty 217 Oct 2022

NCT: national clinical trial.
a Denotes industry-sponsored or cosponsored trial.

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  22. Cip J, Widemschek M, Luegmair M, et al. Conventional versus computer-assisted technique for total knee arthroplasty: a minimum of 5-year follow-up of 200 patients in a prospective randomized comparative trial. J Arthroplasty. Sep 2014; 29(9): 1795-802. PMID 24906519
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  24. Song EK, Agrawal PR, Kim SK, et al. A randomized controlled clinical and radiological trial about outcomes of navigation-assisted TKA compared to conventional TKA: long-term follow-up. Knee Surg Sports Traumatol Arthrosc. Nov 2016; 24(11): 3381-3386. PMID 26831857
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Coding Section 

Codes  Number  Description 
 CPT 20985 

Computer-assisted surgical navigational procedure for musculoskeletal procedures; image-less (List separately in addition to code for primary procedure) 

  0054T Computer-assisted musculoskeletal surgical navigational orthopedic procedure, with image guidance based on fluoroscopic images (List separately in addition to code for primary procedure) 
  0055T Computer-assisted musculoskeletal surgical navigational orthopedic procedure with image guidance based on CT/MRI images (List separately in addition to code for primary procedure) 
  61783  Stereotactic computer-assisted (navigational) procedure; spinal (List separately in addition to code for primary procedure) 
ICD-10-CM (effective 10/01/15)    Investigational for all codes  
ICD-10-PCS (effective 10/01/15)  8E09XBZ Computer Assisted Procedure of Head and Neck Region
  8E0WXBZ  Computer Assisted Procedure of Trunk Region 
  8E0XXBZ  Computer Assisted Procedure of Upper Extremity 
  8E0YXBZ Computer Assisted Procedure of Lower Extremity 
Type of Service  Surgical   
Place of Service  Inpatient Outpatient   

Procedure and diagnosis codes on Medical Policy documents are included only as a general reference tool for each policy. They may not be all-inclusive.

This medical policy was developed through consideration of peer-reviewed medical literature generally recognized by the relevant medical community, U.S. FDA approval status, nationally accepted standards of medical practice and accepted standards of medical practice in this community, Blue Cross Blue Shield Association technology assessment program (TEC) and other nonaffiliated technology evaluation centers, reference to federal regulations, other plan medical policies and accredited national guidelines.

"Current Procedural Terminology © American Medical Association. All Rights Reserved" 

History From 2014 Forward     

02/07/2024 Annual review, no change to policy intent. Updating coding, rationale and references.
02/08/2023 Annual review, no change to policy intent. Updating rationale and references.)

02/01/2022 

Annual review, no change to policy intent. Updating description, regulatory status, rationale and references. 

02/01/2021 

Annual review, no change to policy intent. Updating description, guidelines, coding, rationale and references. 

02/06/2020

Annual review, no change to policy intent. Updating background, regulatory status, rationale and references. 

02/20/2019 

Annual review, no change to policy intent. Updating background, rationale and references 

03/05/2018 

Annual review, no change to policy intent. Updating guidelines and coding to include CPT 0396T. 

02/09/2017 

Updating policy to remove investigational status of this procedure and replace policy language with:The use of computer assistance for orthopedic procedures of the pelvis and appendicular skeleton is a technique that is integral to the primary surgery being performed and, therefore, not eligible for separate reimbursement. When billed, there will be no separate or additional payment for charges associated with computer assistance technology. Reimbursement will be based on the payment for the standard surgical procedure(s). 

02/08/2017 

Annual review, no change to policy intent. Updating title, background, description, rationale and references. 

02/09/2016 

Annual review, no change to policy intent. Updating background, description, rationale and references. 

02/12/2015 

Annual review, no change to policy intent. Updated background, regulatory status, rationale and references. Added guidelines and coding. 

02/10/2014

Annual Review. Updated background, rationale and references. No change to policy intent.

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