CAM 70198

Minimally Invasive Hip and Knee Arthroplasty

Category:Surgery   Last Reviewed:December 2020
Department(s):Medical Affairs   Next Review:December 2999
Original Date:April 2004    

Description:
Minimally invasive arthroplasty is a modification of conventional hip and total knee arthroplasty that uses specialized instruments. Along with a decrease in the size of surgical incision, a minimally invasive procedure may indicate reduced disruption of neurovascular tissues, muscle, tendons, and ligaments in comparison with conventional approaches.

The term minimally invasive surgery (MIS) refers to a variety of surgical approaches and procedures. MIS is commonly thought of as a very small incision, however, some "minimally invasive" procedures may describe incision lengths only slightly reduced from the conventional approach, with greater emphasis on approaches to reduce soft-tissue damage. Postoperative pain and rehabilitation protocols may also be changed to facilitate early recovery.

Hip Arthroplasty
Standard total hip arthroplasty (THA) is typically performed using a posterolateral or anterolateral approach, with an incision of 25-30 cm in length. This approach provides complete and continuous observation of the hip. Minimally invasive hip arthroplasty approaches include a single incision, measuring less than 10 cm in length, and two incisions, sometimes as small as 3 cm. The single-incision approach is a modification of the standard posterior, anterolateral, or anterior approaches that are commonly used for hip arthroplasty. However, the two incision approach constitutes a novel approach to hip arthroplasty that uses intermuscular planes to gain access to the hip joint. The anterior incision is used to expose and remove the femoral head and prepare the acetabulum for placement of the acetabular component. A second lateral incision is used to prepare the femur an dplace the femoral component. Using either the single or two-incision approach, the decrease in muscle and tendon trauma is achievd at the expense of complete and continuous observation of the hip.

Total Knee Arthroplasty
Standard total knee arthroplasty (TKA) is typically performed using a medial parapetellar arthrotomy with a 12- to 18 cm skin in cision and eversion of the patella to allow direct visualization of the knee joint. There is no generally accepted definition of a minimally invasive approach in TKA. Minimally invasive approaches have been reported using the same medial approach, or less frequently with a lateral approach. In addition to the smaller incision, the patella my be subluxated instead of everted to reduce the tension on patellar ligaments. In comparison with conventional TKA, there may be no dislocation of the tibiofemoral joint.

Minimally invasive arthroplasty requires the use of specialized surgical instruments to facilitate exposure and guide placement of the prosthesis. In addition to the potential for greater force exerted on soft tissue when acess to the joint is reduced by a smaller opening, a limited visual field has led to an increase in component misplacement and complications. To improve the accuracy of component placement under limited visualization, some surgeons may use fluroscopy or computer-assisted navigation for alignment of prosthetic components.

Related Policies:
70196 Computer-Assisted Surgical Navigation for Conventional Hip and Total Knee Surgery

Policy:
Minimally invasive hip and total knee replacement may be considered MEDICALLY NECESSARY when performed in appropriately selected patients, by surgeons who are adequately trained and experienced in the specific techniques used, and in institutions that support a comprehensive postoperative rehabilitation program. Appropriately selected patients are those would meet criteria for minimally invasive procedures (e.g., non-obese individuals who are motivated to participate in an accelerated rehabilitation program) as well as meeting established criteria for standard hip or total knee replacement.

Policy Guidelines
There are no specific CPT codes for minimally invasive hip or knee arthroplasty.

It is likely that the CPT code 27130 (arthroplasty, acetabular, and proximal femoral prosthetic replacement) or 27447 (arthroplasty, knee, condyle, and plateau; medial AND lateral compartments with or without patella resurfacing (total knee arthroplasty) would be used.

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. However, this policy considers specific applications of an FDA-approved device as investigational. Alternatively, FDA-approved devices may be assessed on the basis of their medical necessity.

Rationale
The potential advantages of minimally invasive hip or total knee arthroplasty are expected primarily for short-term outcomes such as blood loss, length of hospital stay, and rehabilitation. These proposed advantages must be balanced against the possibility of increased operative difficulty, increased operating room time, reduced visibility, and the learning curve associated with any new technique, potentially resulting in an increase in misalignment and other complications such as failure of fixation, instability, dislocation, and infection. Therefore, any improvements in short-term outcomes need to be carefully weighed against the long-term outcomes of minimally invasive surgery (MIS), with a particular focus on complication and revision rates. In addition, outcomes should be compared with conventional hip or knee arthroplasty, which are generally associated with excellent outcomes of long-term improvement in pain and function and low long-term revision rates.

At the time this policy was created in 2004, the medical literature consisted primarily of case series or comparisons of short-term outcomes of MIS with concurrent or historical controls. In a 2003 symposium, three different surgeons reported their results of minimally invasive hip surgery. (1) One published study reported results from 173 patients undergoing 189 arthroplasties—111 with a minimally invasive single-incision approach and 62 with a conventional incision. (2) Compared to the conventional incision group, the mini-incision group had significantly less mean operative time, blood loss, and intraoperative blood transfusion requirements. Good alignment, defined as an acetabular inclination of between 35 and 55 degrees, was reported for 94% of patients in the mini-incision group; alignment was not reported for the conventional incision group. Another study compared the results of minimally invasive hip arthroplasty in 85 patients with a concurrent group of 85 patients undergoing conventional arthroplasty. (3) The choice of approach was generally based on body habitus; i.e., the conventional surgery group had a higher weight and body mass index. Compared to the standard incision group, the mini-incision group had less operative blood loss. There was no significant difference in the incidence of complications between the two groups. No long-term data were available for these studies.

Sculco and colleagues compared the outcomes in a series of 42 patients who underwent a minimally invasive single-incision hip arthroplasty (8.8 cm in length) with a consecutive cohort of 42 patients who underwent hip arthroplasty using a conventional incision averaging 23 cm in length. (4) The operative time was slightly less in the minimal incision group, but there were no other differences in outcome, i.e., blood loss, length of stay, nerve palsy, infection, or component malposition. The authors then undertook a study in which patients were randomized to undergo hip arthroplasty using either an 8-cm incision (n=28) versus a 15-cm incision (n=32) and followed up for up for 2 years. There were no significant differences in operative time, length of stay, wound drainage, component position, or complication rate. Fewer patients in the minimal incision group limped at 6 weeks and fewer required the use of a cane (p=0.04). There were no differences at 2 years. The authors concluded that a minimal incision was associated with an earlier return to a normal gait. Howell reported on the outcomes of 50 minimally invasive hip arthroplasties that used an anterolateral approach in 46 patients compared prospectively with a control group of 56 patients who underwent a conventional anterolateral incision. (5) The minimal incision group had a longer operative time, but less blood loss than the control group. The mean length of hospital stay for the minimal incision group was 4.4 days compared to 5.7 days in the control group. Short-term results were also reported for 100 patients using a posterolateral minimal incision and for 100 consecutive cases with a two-incision approach. (6, 7)

The published literature at this time reflected the intense interest, and also controversy, surrounding this procedure. (8, 9) In many instances, minimally invasive hip arthroplasty was instituted at the same time as postoperative pain management protocols, both designed to improve early mobilization and hospital discharge. The relative contribution of these two innovations to the early discharge could not be determined. The role of patient selection was another potential source of bias. For example, case series have generally excluded obese patients, and the considerable lay publicity regarding MIS may have led to self-selection of highly motivated patients. Controlled trials did not demonstrate any superiority of minimally invasive surgery for hip or total knee arthroplasty over conventional approaches.

Limited published data were available in 2004 regarding minimally invasive total knee arthroplasty. The bulk of the literature consisted of descriptions of surgical techniques or case series with either no controls or historical controls. (10-14) This evidence was considered inadequate to permit scientific conclusions.

2005-2009 Updates
Updated literature searches of the MEDLINE database were performed for the following periods: 2004 through June 2005; July 2005 through August 2006; September 2006 through October 2007; November 2007 through June 2008; and July 2008 through May 2009. These literature searches focused on randomized controlled trials that compared minimally invasive procedures with conventional approaches.

Hip Arthroplasty
Three systematic reviews from 2007 to 2009 have reviewed minimally invasive hip arthroplasty. (15-17) Sharma and colleagues conducted a qualitative review of 16 level I or II studies pertaining to the various factors that influence rehabilitation after THA. (15) Five studies were identified that reported use of a minimally invasive surgical approach or smaller incision length (<10 cm). Results of the studies indicated that minimally invasive surgical approaches, combined with aggressive pain control, speed recovery by improving patient compliance to accelerated rehabilitation. The faster recovery did not, however, affect the short-term or intermediate-term endpoint after THA as defined by use of walking aids, Harris hip score, Western Ontario and McMaster Universities Index of Osteoarthritis (WOMAC), Oxford hip score, SF-12 and SF-36 at 6 weeks from the surgery. Results from 5 studies that examined the effect of multimodal pain management indicated that aggressive postoperative pain control alone improves patient compliance in immediate postoperative rehabilitation, which leads to better pain control and hastens functional recovery. Another qualitative systematic review by Ulrich et al found that most comparative studies show general equivalence between minimally invasive and standard approaches, but that more reports show disadvantages (increased complications) than advantages. (16) A quantitative systematic review compared outcomes from 5,285 minimally invasive hip arthroplasties with 1,341 conventional hip arthroplasties. (17) The analysis found a decrease in hospital stay (3.7 days vs. 5.0 days) with MIS, with no significant differences for operating time (80 vs. 87 minutes), blood loss (400 mL vs. 456 mL), Harris hip score (40 vs. 42) or measures of alignment. A number of randomized trials with 20 subjects or less per group have been published. Results of some of the larger randomized trials are described below.

One multicenter study randomized 60 patients to undergo either a conventional (15-cm incision length) or minimally invasive hip arthroplasty (8-cm incision length). (18) Operative time, transfusion requirements, narcotic usage, length of hospital stay, rehabilitation milestones, and complications were similar in both groups. The minimally invasive group had less blood loss at surgery and a lower incidence of a limp at 6-week follow-up. Another randomized study of 219 hips found no significant differences between patients who received an incision of 10 cm or less compared to a 16-cm incision in the conventional group, including operative time, blood loss, pain scores, analgesic use, or rehabilitation outcomes. (19)

Dorr et al. randomized 60 patients to computer-assisted total hip arthroplasty (THA) via a posterior mini (10 cm) or traditionally long (20 cm) incision. (20) Blinding of patients and evaluators was accomplished by lengthening the skin incision to 20 cm after completion of the mini-THA. There was a trend toward an increase in operating time (11 minutes), with no other differences in surgical or radiographic outcomes between groups. Twenty-nine of 30 patients (97%) in the mini-incision group were discharged by the second postoperative day in comparison with 67% of the long-incision group; the average hospital stay was 63 and 74 hours, respectively. Pain scores were slightly lower at discharge (Visual Analogue Scale of 2.2 vs. 3.1). By 6 weeks after surgery, there was no difference in clinical outcomes.

Using a 2-incision approach, Bal et al found that 9 of 89 (10%) hip replacements required repeat surgery compared with 3 of 96 (3%) in a contemporaneous (non-randomized) control group that had single-incision minimally invasive hip arthroplasty. (21) Slower recovery for a two-incision approach has also been reported in comparison with a mini-posterior-incision in a randomized trial involving 72 patients. (22) Some reports (case series) suggest that the posterior approach leads to more postoperative dislocations, but that they can be minimized by repairing the external rotators and capsule in all patients. (23)

Overall, these studies and other case series (24-26) suggest that MIS may be safe in experienced hands in the short term, but do not demonstrate that minimally invasive hip arthroplasty is more beneficial than conventional approaches.

Total Knee Arthroplasty
Kolisek et al found an increase in operating time (69 vs. 59 minutes), similar clinical benefit as measured by the SF-12, Knee Society Score, and Bartlett patella scores, and similar radiographic results with a 9-cm midvastus incision at 6 or 12 weeks’ follow-up. (27) There was no difference between groups in postoperative length of hospital stay, amount of analgesic use, return of knee function, or total blood loss. Another multicenter study randomized 90 patients to mini-midvastus, mini-side-cutting, or standard total knee arthroplasty. (28) Operating times were longer with the minimally invasive approaches (112 vs. 92 minutes); all 3 groups remained in the hospital for 6 days. Radiographic outcomes were significantly poorer in the side-cut group, with significantly more outliers in overall limb alignment (43% vs. 17%) and some measures of component positioning. Karachalios and colleagues reported that functional outcomes were improved in 50 patients who had a mini-midvastus approach in comparison with 50 patients who had conventional total knee arthroplasty when measured up to 9 months after surgery. (29) At 2- to 3-year follow-up, functional outcomes were similar between the two groups. Radiologic examination identified technical errors in 6 patients (12%) in the minimally invasive group, prompting these surgeons to abandon routine use of minimally-invasive techniques. In addition, a retrospective comparative cohort study (100 mini-medial parapatellar vs. 50 standard total knee arthroplasty) with a single high-volume surgeon reported improved postoperative recovery (hospital stay, rehabilitation, narcotic usage, and need for assistive devices at 2 weeks postoperatively), but cautioned about the extensive learning curve (about 50 procedures) required to achieve these results. (30)

Clinical Input Received through Physician Specialty Societies and Academic Medical Centers
In response to requests, input was received through 4 academic medical centers while this policy was under review. 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. Clinical input agreed with the policy, as adopted in October 2009, that minimally invasive procedures may be considered acceptable alternatives to other standard approaches for hip and total knee replacement. Clinical input also agreed on the importance of surgeon training and continued high practice volume for good outcomes with minimally invasive approaches.

Summary
Randomized controlled trials suggest modest postoperative benefits in pain reduction and recovery and similar short- to mid-term outcomes with minimally invasive techniques. It remains unclear whether the postoperative benefits are due to the smaller incisions, reduced soft-tissue trauma, or the change in postoperative pain management protocols. In addition, several studies suggest that an increase in implant malalignment and other complications may increase when minimally invasive procedures are performed outside of high-volume centers with experienced surgeons. Therefore, minimally invasive procedures may be considered an alternative to other approaches when performed at centers experienced in the procedure and by surgeons with appropriate training and practice volume.

References:

  1. Berry DJ, Berger RA, Callaghan JJ et al. Minimally invasive hip arthroplasty. Development, early results, and a critical analysis. Presented at the Annual Meeting of the American Orthopaedic Association, Charleston, South Carolina, June 14, 2003. J Bone Joint Surg Am 2003; 85-A (11):2235-46.
  2. Wenz JF, Gurkan I, Jibodh SR. Mini-incision total hip arthroplasty: a comparative assessment of perioperative outcomes. Orthopedics 2002; 25(10):1031-43.
  3. Goldstein WM, Branson JJ, Berland KA et al. Minimal-incision total hip arthroplasty. J Bone J Surg Am 2003; 85-A (suppl 4):33-8.
  4. Sculco TP, Jordan LC, Walter WL. Minimally invasive total hip arthroplasty: the Hospital for Special Surgery experience. Orthop Clin North Am 2004; 35(2):137-42.
  5. Howell JR, Masri BA, Duncan CP. Minimally invasive versus standard incision anterolateral hip replacement: a comparative study. Orthop Clin North Am 2004; 35(2):153-62.
  6. Hartzband MA. Posterolateral minimal incision for total hip replacement: technique and early results. Orthop Clin North Am 2004; 35(2):119-29.
  7. Berger RA, Duwelius PJ. The two incision minimally invasive total hip arthroplasty: technique and results. Orthop Clin North Am 2004; 35(2):163-72.
  8. Sculco TP. Minimally invasive total hip arthroplasty: in the affirmative. J Arthroplasty 2004; 19(suppl 1):78-80.
  9. Hungerford DS. Minimally invasive total hip arthroplasty: in opposition. J Arthroplasty 2004; 19(suppl 1):81-2.
  10. Goble EM, Justin DF. Minimally invasive total knee replacement; principles and techniques. Orthop Clin North Am 2004; 35(2):235-45.
  11. Tria AJ. Minimally invasive total knee arthroplasty: the importance of instrumentation. Orthop Clin North Am 2004; 35(2):227-34.
  12. Bonutti PM, Mont MA, Kester MA. Minimally invasive total knee arthroplasty: a 10-feature evolutionary approach. Orthop Clin North Am 2004; 35(2):217-26.
  13. Laskin RS, Beksac B, Phongjunakorn A et al. Minimally invasive total knee replacement through a mini-midvastus incision: an outcome study. Clin Orthop Rel Res 2004; 428:74-81.
  14. Haas SB, Cook S, Beksac B. Minimally invasive total knee replacement through a mini midvastus approach: a comparative study. Clin Orthop Relat Res 2004; 428:68-73.
  15. Sharma V, Morgan PM, Cheng EY. Factors influencing early rehabilitation after THA: a systematic review. Clin Orthop Relat Res 2009; 467(6):1400-11.
  16. Ulrich SD, Bonutti PM, Seyler TM et al. Outcomes-based evaluations supporting computer-assisted surgery and minimally invasive surgery for total hip arthroplasty. Expert Rev Med Devices 2007; 4(6):873-83.
  17. Mahmood A, Zafar MS, Majid I et al. Minimally invasive hip arthroplasty: a quantitative review of the literature. Br Med Bull 2007; 84:37-48.
  18. Chimento GF, Pavone V, Sharrock N, et al. Minimally invasive total hip arthroplasty: a prospective randomized study. J Arthroplasty 2005; 20(2):139-44.
  19. Ogonda L, Wilson R, Archbold P et al. A minimal-incision technique in total hip arthroplasty does not improve early postoperative outcomes. A prospective, randomized, controlled trial. J Bone Joint Surg Am 2005; 87(4):701-10.
  20. Dorr LD, Maheshwari AV, Long WT et al. Early pain relief and function after posterior minimally invasive and conventional total hip arthroplasty. A prospective, randomized, blinded study. J Bone Joint Surg Am 2007; 89(6):1153-60.
  21. Bal BS, Haltom D, Aleto T et al. Early complications of primary total hip replacement performed with a two-incision minimally invasive technique. J Bone Joint Surg Am 2006; 88(suppl 1, pt 2):221-33.
  22. Pagnano MW, Trousdale RT, Meneghini RM et al. Slower recovery after two-incision than mini-posterior-incision total hip arthroplasty. A randomized clinical trial. J Bone Joint Surg Am 2008; 90(5):1000-6.
  23. Bottner F, Delgado S, Sculco TP. Minimally invasive total hip replacement: the posterolateral approach. Am J Orthop 2006; 35(5):218-24.
  24. Siguier T, Siguier M, Brumpt B. Mini-incision anterior approach does not increase dislocation rate: a study of 1037 total hip replacements. Clin Orthop Relat Res 2004; 426:164-73.
  25. De Beer J, Petruccelli D, Zalzal P et al. Single-incision minimally invasive total hip arthroplasty: length doesn’t matter. J Arthroplasty 2004; 19(8):945-50.
  26. Wright JM, Crockett HC, Delgado S et al. Mini-incision for total hip arthroplasty: a prospective controlled investigation with 5-year follow-up evaluation. J Arthroplasty 2004; 19(5):538-45.
  27. Kolisek FR, Bonutti PM, Hozack WJ et al. Clinical experience using a minimally invasive surgical approach for total knee arthroplasty: early results of a prospective randomized study compared to a standard approach. J Arthroplasty 2007; 22(1):8-13.
  28. Chin PL, Foo LS, Yang KY et al. Randomized controlled trial comparing the radiologic outcomes of conventional and minimally invasive techniques for total knee arthroplasty. J Arthroplasty 2007; 22(6):800-6.
  29. Karachalios T, Giotikas D, Roidis N et al. Total knee replacement performed with either a mini-midvastus or a standard approach: a prospective randomized clinical and radiological trial. J Bone Joint Surg Br 2008; 90(5):584-91.
  30. King J, Stamper DL, Schaad DC et al. Minimally invasive total knee arthroplasty compared with traditional total knee arthroplasty. Assessment of the learning curve and the postoperative recuperative period. J Bone Joint Surg Am 2007; 89(7):1497-503.

Coding Section

Codes Number Description
CPT 27130 Arthroplasty, acetabular and proximal femoral prosthetic replacement (total hip arthroplasty), with or without autograft or allograft
  27299 Unlisted procedure, pelvis or hip joint
  27447 Arthroplasty, knee, condyle and plateau; medial AND lateral compartments with or without patella resurfacing (total knee arthroplasty)
  27599 Unlisted procedure, femur or knee
ICD-9 Procedure   81.51 Total hip replacement
  81.54 Total knee replacement
ICD-9 Diagnosis   Investigational for all diagnnosis
ICD-10-CM (effective 10/01/15)     Investigational for all diagnnosis
ICD-10-PCS (effective 10/01/15)  0SR90J9  Replacement of Right Hip Joint with Synthetic Substitute, Cemented, Open Approach 
  0SR90JA  Replacement of Right Hip Joint with Synthetic Substitute, Uncemented, Open Approach
  0SR90JZ  Replacement of Right Hip Joint with Synthetic Substitute, Open Approach 
  0SRB0J9  Replacement of Left Hip Joint with Synthetic Substitute, Cemented, Open Approach 
  0SRB0JA Replacement of Left Hip Joint with Synthetic Substitute, Uncemented, Open Approach 
  0SRB0JZ  Replacement of Left Hip Joint with Synthetic Substitute, Open Approach 
  0SRC07Z  Replacement of Right Knee Joint with Autologous Tissue Substitute, Open Approach 
  0SRC0JZ  Replacement of Right Knee Joint with Synthetic Substitute, Open Approach 
  0SRC0KZ  Replacement of Right Knee Joint with Nonautologous Tissue Substitute, Open Approach 
  0SRD07Z  Replacement of Left Knee Joint with Autologous Tissue Substitute, Open Approach 
  0SRD0JZ  Replacement of Left Knee Joint with Synthetic Substitute, Open Approach 
  0SRD0KZ  Replacement of Left Knee Joint with Nonautologous Tissue Substitute, Open Approach 
  0SRT07Z  Replacement of Right Knee Joint, Femoral Surface with Autologous Tissue Substitute, Open Approach 
   0SRT0JZ Replacement of Right Knee Joint, Femoral Surface with Synthetic Substitute, Open Approach 
  0SRT0KZ  Replacement of Right Knee Joint, Femoral Surface with Nonautologous Tissue Substitute, Open Approach 
  0SRU07Z  Replacement of Left Knee Joint, Femoral Surface with Autologous Tissue Substitute, Open Approach 
  0SRU0JZ  Replacement of Left Knee Joint, Femoral Surface with Synthetic Substitute, Open Approach 
  0SRU0KZ  Replacement of Left Knee Joint, Femoral Surface with Nonautologous Tissue Substitute, Open Approach 
  0SRV07Z  Replacement of Right Knee Joint, Tibial Surface with Autologous Tissue Substitute, Open Approach 
  0SRV0JZ  Replacement of Right Knee Joint, Tibial Surface with Synthetic Substitute, Open Approach 
  0SRV0KZ  Replacement of Right Knee Joint, Tibial Surface with Nonautologous Tissue Substitute, Open Approach 
  0SRW07Z  Replacement of Left Knee Joint, Tibial Surface with Autologous Tissue Substitute, Open Approach 
  0SRW0JZ  Replacement of Left Knee Joint, Tibial Surface with Synthetic Substitute, Open Approach 
  0SRW0KZ  Replacement of Left Knee Joint, Tibial Surface with Nonautologous Tissue Substitute, Open Approach 
Type of Service     
Place of Service    

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.

Index
Arthroplasty, Hip or Knee, Minimally Invasive
Hip Replacement, Minimally Invasive
Knee Replacement, Minimally Invasive
Minimally Invasive Hip or Knee Replacement

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 and Blue Shield Association technology assessment program (TEC) and other non-affiliated 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 2013 Forward     

12/17/2020 

Annual review, no change to policy intent. 

12/12/2019 

Annual review, no change to policy intent. 

12/21/2018 

Annual review, no change to policy intent 

12/20/2017 

Annual review, no change to policy intent. 

12/05/2016 

Annual review, no change to policy intent. 

11/05/2015 

Annual review, no change to policy intent. Adding ICD10 coding. 

12/04/2014 

Annual review, no change to policy intent. Added policy guidelines, key words and coding. 

12/09/2013

Annual review.  Added related policies and benefit applications.


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