Autologous Chondrocyte Implantation for Focal Articular Cartilage Lesions - CAM 70148
Description:
A variety of procedures are being developed to resurface articular cartilage defects. Autologous chondrocyte implantation involves harvesting chondrocytes from healthy tissue, expanding the cells in vitro, and implanting the expanded cells into the chondral defect. Second- and third-generation techniques include combinations of autologous chondrocytes, scaffolds, and growth factors.
Summary of Evidence
For individuals who have focal articular cartilage lesion(s) of the weight-bearing surface of the femoral condyles, trochlea, or patella who receive autologous chondrocyte implantation, the evidence includes systematic reviews, randomized controlled trials (RCTs), and observational studies. Relevant outcomes are symptoms, change in disease status, morbid events, functional outcomes, and quality of life. There is a large body of evidence on autologous chondrocyte implantation for the treatment of focal articular cartilage lesions of the knee. For large lesions, autologous chondrocyte implantation results in better outcomes than microfracture, particularly in the long term. In addition, there is a limit to the size of lesions that can be treated with osteochondral autograft transfer, due to a limit on the number of osteochondral cores that can be safely harvested. As a result, autologous chondrocyte implantation has become the established treatment for large articular cartilage lesions in the knee. In 2017, first-generation autologous chondrocyte implantation with a collagen cover was phased out and replaced with an autologous chondrocyte implantation preparation that seeds the chondrocytes onto a bioresorbable collagen sponge. Although the implantation procedure for this second-generation autologous chondrocyte implantation is less technically demanding, studies to date have not shown improved outcomes compared with first-generation autologous chondrocyte implantation. Some evidence has suggested an increase in hypertrophy (overgrowth) of the new implant that may exceed that of the collagen membrane-covered implant. Long-term studies with a larger number of patients will be needed to determine whether this hypertrophy impacts graft survival. Based on mid-term outcomes that approximate those of first-generation autologous chondrocyte implantation and the lack of alternatives, second-generation autologous chondrocyte implantation may be considered an option for large disabling full-thickness cartilage lesions of the knee. The evidence is sufficient to determine that the technology results in an improvement in the net health outcome.
For individuals who have focal articular cartilage lesions of joints other than the knee who receive autologous chondrocyte implantation, the evidence includes case series, systematic reviews of case series, and a network meta-analysis of prospective (none of which evaluated autologous chondrocyte implantation) and retrospective studies. Relevant outcomes are symptoms, change in disease status, morbid events, functional outcomes, and quality of life. The greatest amount of literature is for autologous chondrocyte implantation of the talus. Comparative trials are needed to determine whether autologous chondrocyte implantation improves outcomes for lesions in joints other than the knee. The evidence is insufficient to determine that the technology results in an improvement in the net health outcome.
Additional Information
Not applicable
Background
ARTICULAR CARTILAGE LESIONS
Damaged articular cartilage typically fails to heal on its own and can be associated with pain, loss of function, and disability and may lead to debilitating osteoarthritis over time. These manifestations can severely impair a patient’s activities of daily living and adversely affect quality of life.
Treatment
Conventional treatment options include débridement, subchondral drilling, microfracture, and abrasion arthroplasty. Débridement involves the removal of synovial membrane, osteophytes, loose articular debris, and diseased cartilage and is capable of producing symptomatic relief. Subchondral drilling, microfracture, and abrasion arthroplasty attempt to restore the articular surface by inducing the growth of fibrocartilage into the chondral defect. Compared with the original hyaline cartilage, fibrocartilage has less capability to withstand shock or shearing force and can degenerate over time, often resulting in the return of clinical symptoms. Osteochondral grafts and autologous chondrocyte implantation (ACI) attempt to regenerate hyaline-like cartilage and thereby restore durable function. Osteochondral grafts for the treatment of articular cartilage defects are discussed in evidence review 7.01.78.
With ACI, a region of healthy articular cartilage is identified and biopsied through arthroscopy. The tissue is sent to a facility licensed by the U.S. Food and Drug Administration (FDA) where it is minced and enzymatically digested, and the chondrocytes are separated by filtration. The isolated chondrocytes are cultured for 11 to 21 days to expand the cell population, tested, and then shipped back for implantation. With the patient under general anesthesia, an arthrotomy is performed, and the chondral lesion is excised up to the normal surrounding cartilage. Methods to improve the first-generation ACI procedure have been developed, including the use of a scaffold or matrix-induced autologous chondrocyte implantation (MACI) composed of biocompatible carbohydrates, protein polymers, or synthetics. The only FDA-approved MACI product to date is supplied in a sheet, which is cut to size and fixed with fibrin glue. This procedure is considered technically easier and less time consuming than the first-generation technique, which required suturing of a periosteal or collagen patch and injection of chondrocytes under the patch.
Desired features of articular cartilage repair procedures are the ability (1) to be implanted easily, (2) to reduce surgical morbidity, (3) not to require harvesting of other tissues, (4) to enhance cell proliferation and maturation, (5) to maintain the phenotype, and (6) to integrate with the surrounding articular tissue. In addition to the potential to improve the formation and distribution of hyaline cartilage, use of a scaffold with MACI eliminates the need for harvesting and suture of a periosteal or collagen patch. A scaffold without cells may also support chondrocyte growth.
Regulatory Status
The culturing of chondrocytes is considered by FDA to fall into the category of manipulated autologous structural cells, which are subject to a biologic licensing requirement. In 1997, Carticel® (Genzyme; now Vericel) received FDA approval for the repair of clinically significant, "... symptomatic cartilaginous defects of the femoral condyle (medial lateral or trochlear) caused by acute or repetitive trauma .… ."
In December 2016, MACI® (Vericel) FDA approved for "the repair of symptomatic, single or multiple full-thickness cartilage defects of the knee with or without bone involvement in adults." MACI® consists of autologous chondrocytes which are cultured onto a bioresorbable porcine-derived collagen membrane. In 2017, production of Carticel® was phased out, and MACI® is the only ACI product available in the United States.
A number of other second-generation methods for implanting autologous chondrocytes in a biodegradable matrix are currently in development or testing or are available outside of the United States. They include Atelocollagen (Koken), a collagen gel; Bioseed® C (BioTissue Technologies), a polymer scaffold; CaReS (Ars Arthro), collagen gel; Cartilix (Biomet), a polymer hydrogel; Chondron (Sewon Cellontech), a fibrin gel; Hyalograft C (Fidia Advanced Polymers), a hyaluronic acid-based scaffold; NeoCart (Histogenics), an ACI with a 3-dimensional chondromatrix in a phase 3 trial; and Novocart®3D (Aesculap Biologics), a collagen-chondroitin sulfate scaffold in a phase 3 trial. ChondroCelect® (TiGenix), a characterized chondrocyte implantation with a completed phase 3 trial, uses a gene marker profile to determine in vivo cartilage-forming potential and thereby optimizes the phenotype (eg, hyaline cartilage vs fibrocartilage) of the tissue produced with each ACI cell batch. Each batch of chondrocytes is graded based on the quantitative gene expression of a selection of positive and negative markers for hyaline cartilage formation.
Related Policies
10110 Continuous Passive Motion (CPM) in the Home Setting
70115 Meniscal Allografts and Other Meniscal Implants
70178 Autografts and Allografts in the Treatment of Focal Articular Cartilage Lesions
80152 Orthopedic Applications of Stem-Cell Therapy
Policy
Autologous chondrocyte implantation may be considered MEDICALLY NECESSARY for the treatment of disabling full-thickness articular cartilage defects of the knee caused by acute or repetitive trauma, when all of the following criteria are met:
- Adolescent patients should be skeletally mature with documented closure of growth plates (e.g., 15 years or older). Adult patients should be too young to be considered an appropriate candidate for total knee arthroplasty or other reconstructive knee surgery (e.g., younger than 55 years)
- Focal, full-thickness (grade III or IV) unipolar lesions of the patella or the weight-bearing surface of the femoral condyles or trochlea at least 1.5 cm2 in size
- Documented minimal to absent degenerative changes in the surrounding articular cartilage (Outerbridge grade II or less), and normal-appearing hyaline cartilage surrounding the border of the defect
- Normal knee biomechanics or alignment and stability achieved concurrently with autologous chondrocyte implantation
Autologous chondrocyte implantation for all other joints, including talar, and any indications other than those listed above is investigational and/or unproven and therefore NOT MEDICALLY NECESSARY.
Policy Guidelines
For smaller lesions (e.g., < 4 cm2), if debridement is the only prior surgical treatment, then consideration should be given to marrow-stimulating techniques before autologous chondrocyte implantation is performed.
The average defect size reported in the literature is about 5 cm2; many studies treated lesions as large as 15 cm2.
Severe obesity (e.g., body mass index > 35 kg/m2) may affect outcomes due to the increased stress on weight-bearing surfaces of the joint.
Misalignment and instability of the joint are contraindications. Therefore, additional procedures, such as repair of ligaments or tendons or creation of an osteotomy for realignment of the joint, may be performed at the same time. In addition, meniscal allograft transplantation may be performed in combination, either concurrently or sequentially, with autologous chondrocyte implantation. The charges for the culturing component of the procedure are submitted as part of the hospital bill.
The entire matrix-induced autologous chondrocyte implantation procedure consists of 4 steps: (1) initial arthroscopy and biopsy of normal cartilage, (2) culturing of chondrocytes on an absorbable collagen matrix, (3) a separate arthrotomy to place the implant, and (4) postsurgical rehabilitation. The initial arthroscopy may be scheduled as a diagnostic procedure; as part of this procedure, a cartilage defect may be identified, prompting biopsy of normal cartilage in anticipation of a possible chondrocyte transplant. The biopsied material is then sent for culturing and returned to the hospital when the implantation procedure (i.e., arthrotomy) is scheduled.
Coding
See the Codes table for details.
Rationale
This evidence review was created in July 1996 with searches of the PubMed database. The most recent literature update was performed through February 16, 2023.
Evidence reviews assess the clinical evidence to determine whether the use of a 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 to 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 a technology, 2 domains are examined: the relevance and the quality and credibility. To be relevant, studies must represent one 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. Randomized controlled trials 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.
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.
Autologous Chondrocyte Implantation for Focal Articular Cartilage Lesion(s) of the Knee
Clinical Context and Therapy Purpose
The purpose of autologous chondrocyte implantation in individuals with focal articular cartilage lesion(s) of the weight-bearing surface of the femoral condyles, trochlea, or patella is to provide a treatment option that is an alternative to or an improvement on existing therapies.
The following PICO was used to select literature to inform this review.
Populations
The relevant population of interest is individuals with focal articular cartilage lesion(s) of the weight-bearing surface of the femoral condyles, trochlea, or patella.
Interventions
The treatment being considered is autologous chondrocyte implantation. The first stage of implantation includes arthroscopy to obtain a biopsy of healthy articular cartilage and the second stage is the arthrotomy.
Comparators
The comparators of interest are marrow stimulation or osteochondral autograft.
Outcomes
The general outcomes of interest are symptoms, change in disease status, morbid events, functional outcomes, and quality of life.
Positive outcomes include easy implantation, reduction in surgical morbidity, no need to harvest other tissues, enhancement of cell proliferation and maturation, maintenance of phenotype, and integration with surrounding tissues.
Negative outcomes include hypertrophy of the transplant, disturbed fusion of the regenerative and healthy surrounding cartilage, inadequate regenerative cartilage, and delamination.5
The existing literature evaluating autologous chondrocyte implantation has varying lengths of follow-up, ranging from 1 to 10 years. Therefore, a minimum of 1 year of follow-up is considered necessary to demonstrate efficacy.
Table 1 describes several outcome measurement tools used in the following studies.
Table 1. Patient-Reported Outcome Measurement Toolsa
Name | Description | Scoring | MCID |
CKRS and mCKRS6 | Measure symptoms, sports activity, and ADL functioning | Likert-type scale; total range 0 – 100, 100 being best-function CKRS: 22 questions in 6 areas:
12 questions, 8 included in summary score:
|
6 mo = 14.0 12 mo = 26.07, |
EQ-5 VAS8 | Generic questionnaire for measuring HRQoL Measures patients’ perceptions of their current overall health and can be used to track changes over time |
5 dimensions of health:
|
Not available |
IKDC Subjective Knee Form9 | Assesses symptoms, daily activity, and sports function caused by conditions affecting the knee. | 18 items are totaled and expressed as a percentage of the maximum possible score 100% indicates the absence of symptoms and higher functioning levels |
Change score < 11.5% indicates patient likely does not perceive improvement. Change score > 20.5% indicates patient likely perceives improvement. |
KOOS10,11 | Assesses patients’ opinion about their knee and associated problems, both short- and long-term Items selected based on WOMAC |
42 items in 5 separately scored subscales:
|
For knee injuries (MDC):
|
KSS12 | Rates knee and patients’ functional abilities before and after total knee replacement | Knee score section (KS-KS): 7 items Functional score section (KS-FS): 3 items Each section scored 0 – 50, with lower scores indicating worse knee conditions |
KS-KS: 5.3 – 5.9 KS-FS: 6.1 – 6.4 |
LKQ11 | Measures outcomes of knee ligament surgery, with emphasis on evaluation of instability and corresponding to patient’s own opinion | 8 items with individual scoring scales:
|
8.9 – 10.1 (MDC) |
OKS11 | For patients undergoing total knee arthroscopy to assess their knee-related health status and benefits of treatment | 12 items pertaining to knee pain and function
|
Not available |
SF-12 and SF-3613,14,15,16 | Both are health-related quality of life surveys covering 8 domains including physical and mental components SF-12 is a shortened version of SF-36. |
8 domains:
Physical and mental components are scored separately Scores range 0 – 100:
|
4.3 – 5.0 (physical component) |
TAS11 | Developed to complement Lysholm score Grades activity based on work and sports activities |
Graduated list of ADLs, recreation, and competitive sports (11 options); patient selects 1 item that best represents their current level of activity Possible score range, 0 – 10:0 = sick leave or disability pension due to knee problems
|
1.0 (MDC) |
WOMAC11 | Assessment of ADL, functional mobility, gait, general health, and quality of life | 24 items broken into 3 subscales:
|
For Knee OA (MDC):
|
ADL: activities of daily living; CKRS: Cincinnati Knee Rating System; EQ-5 VAS: EuroQol 5 Dimensions Visual Analog Scale; HRQoL: health-related quality of life; IKDC: International Knee Documentation Committee; KOOS: Knee Injury and Osteoarthritis Outcome Score; KSS: Knee Society Score; LKQ: Lysholm Knee Questionnaire; mCKRS: modified Cincinnati Knee Rating System; MCID: minimal clinically important difference; MDC: minimum detectable change; OA: osteoarthritis; OKS: Oxford Knee Score; SF-12: 12-Item Short-Form Health Survey; SF-36: 36-Item Short-Form Health Survey; TAS: Tegner Activity Scale; WOMAC: Western Ontario and McMaster Universities Osteoarthritis Index.
a All surveys are either patient-completed or observer-administered to patient.
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
Systematic Reviews
Cartilage Repair Procedures
Several systematic reviews with or without meta-analysis have evaluated autologous chondrocyte implantation and other cartilage repair techniques for the knee. The studies included, characteristics of the systematic reviews, and key findings are outlined in Tables 2, 3, and 4, respectively.
A systematic review by Migliorini and colleagues (2022) reported findings from 47 publications that described outcomes in at least 5 patients who underwent matrix-induced autologous chondrocyte implantation (MACI) or cell-free autologous matrix-induced chondrogenesis (AMIC) for chondral defects of the knee, including 38 prospective studies and 9 retrospective studies.17 Risk of bias was not reported for individual studies, but the proportion of studies at unclear or high risk of bias ranged from approximately 20% to more than 75% in each bias domain. The authors reported significantly higher Lysholm Knee Questionnaire scores and International Knee Documentation Committee scores with AMIC relative to MACI, and significantly higher rates of treatment failure with MACI relative to AMIC. The nature of the statistical analysis limits interpretation of these findings; the authors pooled data from all studies for analysis without weighting, using simple statistical tests to compare distributions of continuous values (via t-tests) or proportions (via Chi-square); differences in baseline characteristics and various patient-reported outcome and complication measures were tested without adjustment for multiple comparisons. The time at which the outcomes were assessed was not reported, and several reported outcomes were not defined (such as hypertrophy and treatment failure).
Dhillon et al. (2022) performed a systematic review of randomized trials comparing collagen membrane-cultured third-generation autologous chondrocyte implantation to microfracture (MF) in patients with focal chondral defects of the knee.18 Among 368 patients enrolled in 5 RCTs, mean follow-up ranged from 2 to 6 years. Two RCTs were determined to be at high risk of bias related to lack of blinding. Findings for patient-reported outcomes were mixed; 1 trial reported significantly greater improvement in postoperative International Knee Documentation Committee scores with autologous chondrocyte implantation relative to MF, while another indicated no difference in improvement between groups. Similarly, 1 trial reported significantly greater improvement from baseline in Lysholm Knee Questionnaire scores with autologous chondrocyte implantation relative to MF, while 2 trials reported no difference in improvement between groups. Both studies evaluating Tegner Activity Scale scores noted significantly greater improvement from baseline with autologous chondrocyte implantation relative to MF. Treatment failure rates were low with autologous chondrocyte implantation (ranging from 0% to 1.8%); failure rates ranged from 2.5% to 8.3% in MF groups.
A 2022 systematic review by Angele et al. reported outcomes of randomized trials of cartilage repair techniques for localized cartilage defects of the knee with minimum 5-year follow-up.19 The 6 included RCTs comprised 520 patients, with mean follow-up ranging from 5 to 16 years; 1 trial (SUMMIT, discussed in the section below detailing RCTs) compared matrix-induced autologous chondrocyte implantation (MACI) to MF, and 3 compared other autologous chondrocyte implantation techniques to either MF or osteochondral autograft transplantation. All trials were considered to be at high risk of bias due to lack of blinding. The trial comparing MACI to MF indicated superior outcomes in the KOOS pain, function, and activities of daily living subscales with MACI; trials of other autologous chondrocyte implantation modalities produces mixed results, with 2 trials indicating no difference relative to MF in overall KOOS or other patient-reported outcome measures, 1 trial indicating significant improvement in overall KOOS relative to MF in a subgroup of patients with symptom onset within 3 years prior to intervention, and 1 trial indicating superior Cincinnati Knee Rating System scores at 10-year follow-up relative to osteochondral autograft transfer.
Abraamyan et al. (2022 ) completed a systematic review with meta-analysis that evaluated cartilage repair techniques, including microfracture, augmented microfracture, and autologous chondrocyte implantation/matrix-induced autologous chondrocyte implantation.20 The authors included a total of 14 RCTs (N = 775), and changes from baseline in the 5 KOOS subscales, including KOOS Sport, KOOS Quality of Life, KOOS Symptoms, KOOS Pain, and KOOS Activities of Daily Living, were measured. Only the KOOS Sport subscale demonstrated statistically significant benefits with autologous chondrocyte implantation/matrix-induced autologous chondrocyte implantation procedures compared with microfracture (p = .02). The mean delta KOOS Sport after autologous chondrocyte implantation/matrix-induced autologous chondrocyte implantation procedures was 9.9 points greater than after microfracture and 11.7 points greater than after augmented microfracture. Comparisons between surgical techniques for the other subscales did not reach statistical significance.
In 2020, Gou et al. evaluated clinical outcomes among patients with fractures of knee cartilage who were treated with autologous chondrocyte implantation (n = 332) or microfracture (n = 327) from 12 RCTs.21 Patient age ranged from 25 to 41 years, with the majority of patients male. Treatment follow-up ranged from 1.5 to 15 years. There were diverse types of autologous chondrocyte implantation performed among the studies including matrix-induced autologous chondrocyte implantation, NeoCart, autologous chondrocyte implantation with periosteum, and ChondroCelect. Outcomes included an overall clinical score, KOOS subdomains of activities of daily living and function, quality of life, pain relief score, and failure/operation rate. Results revealed no significant differences between the interventions with regard to improvement in International Knee Documentation Committee and Lysholm scores or overall KOOS measures at 1, 2, and 5 years of follow-up. There was also no difference between the groups with regard to failure rate at 2, 3, and 5 years. Autologous chondrocyte implantation was associated with significant improvements in activities of daily living at 5 years or less of follow-up as compared to microfracture as well as improvement in quality of life and pain relief at 5 and 2 year follow-up examinations, respectively. Major limitations of this systematic review and meta-analysis included the small number of eligible RCTs in the final analysis with regard to length of follow-up and that the studies included in the meta-analysis utilized a variety of autologous chondrocyte implantation techniques, scales and scores for outcome measures, and recruited patients with different lesion sizes. Plus, blinding of the patients or surgeons was difficult to perform given the 2-step procedure of autologous chondrocyte implantation.
Zamborsky et al. (2020) completed a systematic review and network meta-analysis that evaluated the most appropriate surgical interventions for patients with knee articular cartilage defects.22 The authors included a total of 21 articles (from 12 RCTs) in their analysis with a total population of 891 patients. Follow-up varied widely among the included studies, ranging from 12 months to 15 years. Of the surgical interventions evaluated, microfracture was associated with significantly higher failure rates compared to autologous chondrocyte implantation at 10 years of follow-up (relative risk [RR], 0.12; 95% confidence interval [CI]; 0.04 to 0.39). No significant differences in failure rates were seen between microfracture and osteochondral autograft transplantation, matrix-induced autologous chondrocyte implantation, or characterized chondrocyte implantation at 2, 5, and 10 years of follow-up. Osteochondral autograft transplantation was associated with significantly more excellent or good results at > 3 years of follow-up as compared to microfracture, whereas microfracture was associated with significantly poorer results as compared to autologous chondrocyte implantation and matrix-induced autologous chondrocyte implantation. No significant differences between the interventions were noted regarding reintervention, biopsy types, or adverse events. Based on efficacy and safety, autologous chondrocyte implantation was ranked as the best intervention for failure outcome at 10 years of follow-up, followed by osteochondral autograft transplantation, then microfracture. Microfracture was consistently ranked worse than cartilage repair techniques for other outcomes including quality of tissue repair and return-to-activity rates.
Riboh et al. (2017) reported on a network meta-analysis assessing the comparative efficacy of cartilage repair procedures of the knee.23 Nineteen RCTs from 15 separate cohorts (N = 855) were included. The procedures selected for the network analysis were matrix-induced autologous chondrocyte implantation, autologous chondrocyte implantation with a collagen membrane, autologous chondrocyte implantation with a periosteal membrane, osteochondral autograft transfer, and microfracture. Outcomes evaluated included graft hypertrophy, hyaline cartilage, Lysholm Knee Scoring System score, reoperation in the short-, mid-, and long-term, and Tegner Activity Scale score. The rank order of treatment efficacy, taking into account all outcome measures, was autologous chondrocyte implantation with a collagen membrane, osteochondral autograft transfer, matrix-induced autologous chondrocyte implantation, autologous chondrocyte implantation with a periosteal membrane, and microfracture. Another systematic review of surgical treatments of cartilage defects of the knee by Devitt et al. (2017)24 included a subset of the RCTs in the Riboh et al. (2017) review.
Mundi et al. (2016) reported on a systematic review of level I studies for cartilage restoration of the knee.25 Included were 12 randomized trials (N = 765) and a mean lesion size of 3.9 cm2. Five trials compared autologous chondrocyte implantation with marrow stimulation, 3 compared autologous chondrocyte implantation with osteochondral autograft transfer, 1 compared osteochondral autograft transfer with microfracture, and 3 compared different generations of autologous chondrocyte implantation. Eleven of the 12 trials were conducted in Europe. Four trials reported significant differences in function with autologous chondrocyte implantation versus marrow stimulation. However, a meta-analysis showed no significant differences in pain or function between the 2 treatments at 24-month follow-up. The quality of the evidence was rated as poor to moderate, and only 4 trials reported a sample size calculation. Although meta-analysis could not be performed on the other comparisons, 5 of 6 trials found no significant difference in outcomes between autologous chondrocyte implantation and osteochondral autograft transfer or different generations of autologous chondrocyte implantation. The percentage of grafts that failed and the relationship between lesion size and success rate were not assessed in this review.
A systematic review by Harris et al. (2010) comparing autologous chondrocyte implantation with other cartilage repair or restoration techniques, included 13 RCTs and nonrandomized trials of 917 participants who underwent autologous chondrocyte implantation (n = 604), microfracture (n = 271), or osteochondral autograft transfer (n = 42).26 The mean study quality was rated as 54 (out of 100), with no studies considered of good or excellent quality, 7 considered fair, and 6 considered poor. Four studies compared different generations of autologous chondrocyte implantation, finding no difference in outcomes but higher complication rates with open, periosteal cover, first-generation autologous chondrocyte implantation. At 1- to 5-year follow-up, 3 of 7 studies showed better clinical outcomes after autologous chondrocyte implantation than after microfracture, 1 showed better outcomes after microfracture, and 3 showed no difference between these treatments. Clinical outcomes after microfracture deteriorated after 18 to 24 months in 3 of 7 studies. Studies comparing autologous chondrocyte implantation with osteochondral autograft transfer showed similar short-term clinical outcomes, with more rapid improvement but an increase in arthrofibrosis and donor-site morbidity following osteochondral autograft transfer. Younger patients with a shorter preoperative duration of symptoms and fewer prior surgical procedures had the best outcomes after surgical intervention. A defect size greater than 4 cm2 was the only factor predictive of better outcomes when autologous chondrocyte implantation was compared with other surgical techniques.
Table 2. Comparison of Trials/Studies Included in Systematic Reviews of Autologous Chondrocyte Implantation for Cartilage Repair of the Knee
Study | Harris et al. (2010)26 | Mundi et al. (2016)25 | Riboh et al. (2017)23 | Gou et al. (2020)21 | Zamborsky et al. (2020)22 | Abraamyan et al. (2022)20 | Angele et al. (2022)19 | Dhillon et al. (2022)18 | Migliorini et al. (2022)17 |
Akgun et al. (2015) | ⚫ | ||||||||
Anders et al. (2013) | ⚫ | ⚫ | |||||||
Astur et al. (2018) | ⚫ | ||||||||
Bartlett et al. (2005) | ⚫ | ⚫ | ⚫ | ⚫ | ⚫ | ||||
Basad et al. (2004) | ⚫ | ||||||||
Basad et al. (2010) | ⚫ | ⚫ | ⚫ | ⚫ | ⚫ | ⚫ | ⚫ | ||
Basad et al. (2015) | ⚫ | ||||||||
Becher et al. (2017) | ⚫ | ||||||||
Behrens et al. (2006) | ⚫ | ||||||||
Bentley et al. (2003) | ⚫ | ⚫ | ⚫ | ||||||
Bentley et al. (2012) | ⚫ | ⚫ | ⚫ | ||||||
Brittberg et al. (2018) | ⚫ | ⚫ | ⚫ | ⚫ | ⚫ | ⚫ | |||
Chung et al. (2014) | ⚫ | ||||||||
Cole et al. (2011) | ⚫ | ||||||||
Crawford et al. (2012) | ⚫ | ⚫ | ⚫ | ⚫ | ⚫ | ⚫ | |||
Cvetanovich et al. (2017) | ⚫ | ||||||||
de Girolamo et al. (2019) | ⚫ | ||||||||
Dozin et al. (2005) | ⚫ | ⚫ | |||||||
Ebert et al. (2011) | ⚫ | ||||||||
Ebert et al. (2012) | ⚫ | ||||||||
Ebert et al. (2012) | ⚫ | ||||||||
Ebert et al. (2015) | ⚫ | ||||||||
Ebert et al. (2017) | ⚫ | ||||||||
Ebert et al. (2017) | ⚫ | ||||||||
Efe et al. (2012) | ⚫ | ||||||||
Enea et al. (2013) | ⚫ | ||||||||
Enea et al. (2015) | ⚫ | ||||||||
Ferruzzi et al. (2008) | ⚫ | ⚫ | |||||||
Fossum et al. (2019) | ⚫ | ||||||||
Gille et al. (2013) | ⚫ | ||||||||
Gobbi et al. (2009) | ⚫ | ||||||||
Gooding et al. (2006) | ⚫ | ⚫ | ⚫ | ||||||
Gudas et al. (2005) | ⚫ | ⚫ | |||||||
Gudas et al. (2009) | ⚫ | ⚫ | |||||||
Gudas et al. (2012) | ⚫ | ⚫ | ⚫ | ||||||
Gudas et al. (2019) | ⚫ | ||||||||
Hoburg et al. (2019) | ⚫ | ||||||||
Horas et al. (2003) | ⚫ | ⚫ | ⚫ | ||||||
Ibarra et al. (2021) | ⚫ | ||||||||
Kim et al. (2017) | ⚫ | ||||||||
Kim et al. (2020) | ⚫ | ||||||||
Knutsen et al. (2004) | ⚫ | ⚫ | ⚫ | ⚫ | ⚫ | ||||
Knutsen et al. (2007) | ⚫ | ⚫ | ⚫ | ⚫ | |||||
Knutsen et al. (2016) | ⚫ | ⚫ | ⚫ | ||||||
Koh et al. (2016) | ⚫ | ||||||||
Kon et al. (2009) | ⚫ | ||||||||
Kon et al. (2011) | ⚫ | ||||||||
Lahner et al. (2018) | ⚫ | ||||||||
Lim et al. (2012) | ⚫ | ||||||||
Lopez-Alocorocho et al. (2018) | ⚫ | ||||||||
Macmull et al. (2011) | ⚫ | ||||||||
Macmull et al. (2012) | ⚫ | ||||||||
Marlovits et al. (2012) | ⚫ | ||||||||
Meyerkort et al. (2014) | ⚫ | ||||||||
Migliorini et al. (2021) | ⚫ | ||||||||
Migliorini et al. (2021) | ⚫ | ||||||||
Nawaz et al. (2014) | ⚫ | ||||||||
Nejadnik et al. (2010) | ⚫ | ||||||||
Niemeyer et al. (2008) | ⚫ | ||||||||
Niemeyer et al. (2016) | ⚫ | ||||||||
Niemeyer et al. (2019) | ⚫ | ⚫ | ⚫ | ||||||
Saris et al. (2008) | ⚫ | ⚫ | ⚫ | ⚫ | |||||
Saris et al. (2009) | ⚫ | ⚫ | ⚫ | ⚫ | ⚫ | ||||
Saris et al. (2014) | ⚫ | ⚫ | ⚫ | ||||||
Schagemann et al. (2018) | ⚫ | ||||||||
Schiavonni Panni et al. (2018) | ⚫ | ||||||||
Schneider et al. (2011) | ⚫ | ||||||||
Schüttler et al. (2019) | ⚫ | ||||||||
Shive et al. (2015) | ⚫ | ||||||||
Siebold et al. (2018) | ⚫ | ||||||||
Solheim et al. (2018) | ⚫ | ||||||||
Stanish et al. (2013) | ⚫ | ⚫ | |||||||
Steinwachs et al. (2019) | ⚫ | ||||||||
Ulstein et al. (2014) | ⚫ | ⚫ | |||||||
Van Assche et al. (2010) | ⚫ | ⚫ | |||||||
Vanlauwe et al. (2011) | ⚫ | ⚫ | ⚫ | ⚫ | ⚫ | ||||
Visna et al. (2004)] | ⚫ | ||||||||
Volz et al. (2017) | ⚫ | ⚫ | |||||||
Wondrasch et al. (2015) | ⚫ | ||||||||
Zeifang et al. (2010) | ⚫ | ⚫ | ⚫ | ⚫ |
Table 3. Systematic Review and Meta-Analysis Characteristics
Study | Dates | Studies | Participants | N (Range) | Design | Duration |
Harris et al. (2010)26 | 2003 to 2010 | 13 | Patients who received any-generation ACI vs other cartilage repair technique for focal cartilage defects of the knee | 917 (21 to 118)a | 13 publications (9 RCT cohorts, 2 prospective non-randomized cohorts) | 12 to 60 months |
Mundi et al. (2016)25 | 2003 to 2012 | 12 | Patients who received marrow stimulation (including MF), ACI, or OAT for isolated cartilage lesions or chondral defects of the knee | 765 (21 to 118) | 11 RCTs | 12 to 24 months |
Riboh et al. (2017)23 | 2003 to 2014 | 19 | Patients who received any cartilage repair technique for articular cartilage defects of the knee | 855 (21 to 118) | 19 publications (15 RCT cohorts) | 12 to 120 months |
Gou et al. (2020)21 | 2004 to 2018 | 12 | Patients who received any-generation ACI vs MF for articular cartilage defects of the knee | 659 (30 to 144) | 12 RCTs | 1.5 to 15 years |
Zamborsky et al. (2020)22 | 2004 to 2018 | 21 | Patients who received any cartilage repair technique for articular cartilage defects of the knee | 891 (30 to 144) | 21 publications (12 RCT cohorts) | 1 to 15 years |
Abraamyan et al. (2022)20 | 2011 to 2020 | 14 | Patients who received any cartilage repair technique for articular cartilage defects of the knee | 775 (NR) | 14 RCTs | 12 to 118 months |
Angele et al. (2022)19 | 2011 to 2018 | 6 | Patients who received any cartilage repair technique for articular cartilage defects of the knee | 520 (40 to 128) | 6 RCTs | 5 to 16 years |
Dhillon et al. (2022)18 | 2010 to 2021 | 5 | Patients who received third-generation ACI vs MF for focal cartilage defects of the knee | 368 (30 to 144) | 5 RCTs | 2 to 6 years |
Migliorini et al. (2022)17 | 2005 to 2021 | 47 | Patients who received AMIC vs MACI for chondral defects of the knee | 1667 (7 to 827) | 12 RCTs, 26 prospective cohort studies, 9 retrospective studies | 12 to 100 months |
ACI: autologous chondrocyte implantation; AMIC: autologous matrix-induced chondrogenesis; MACI: matrix-induced autologous chondrocyte implantation; MF: microfracture; NR: not reported; OAT: osteochondral autograft transfer; RCT: randomized controlled trial.
a N not reported for 1 German-language randomized trial (Basad et al. 2004).
Table 4. Systematic Review and Meta-Analysis Results
Study | Functional scores (IKDC, KOOS, LKQ, and/or TAS) | Pain scores | Need for re-operation |
Harris et al. (2010)26 | |||
Range of N | NR | NR | NR |
Range of effect sizes | NR | NR | NR |
Mundi et al. (2016)25 | |||
Total N | • ACI vs marrow stimulation: 338 • ACI vs MF: 288 |
ACI vs MF: 228 | NR |
Pooled effect (95% CI) | • ACI vs marrow stimulation: SMD 0.47 (-0.19 to 1.13) • ACI vs MF: SMD 0.29 (-0.40 to 0.98) |
ACI vs MF: SMD -0.13 (-0.39 to 0.13) | NR |
I2 (p) | • ACI vs marrow stimulation: 87% (p<.00001) • ACI vs MF: 86% (p<.0001) |
0% (p = .61) | NR |
Riboh et al. (2017)23 | |||
Total N | NR | NR | NR |
Pooled effect (95% CI) | • MACI vs ACI (periosteal): NMD 2.95 (-24.36 to 30.27) • MACI vs MF: NMD -10.67 (-39.77 to 18.43) • MACI vs OAT: NMD 3.00 (-41.97 to 47.91) |
NR | Within 2 years: • ACI (periosteal) vs MACI: OR 0.99 (0.05 to 18.50) • MF vs MACI: OR 2.00 (0.04 to 106.62) • OAT vs MACI: 1.01 (0.01 to 70.29) |
I2 (p) | NR | NR | NR |
Gou et al. (2020)21 | |||
Total N | NR | NR | NR |
Pooled effect (95% CI) | MF vs ACI: • 1-year follow-up: SMD -0.616 (-2.461 to 1.229) • 2-year follow-up: SMD 0.052 (-1.200 to -1.303) • 5-year follow-up: SMD -0.138 (-0.598 to 0.321) |
MF vs ACI (positive values favor ACI): • 1-year follow-up: SMD 2.108 (-0.642 to 4.858) • 2-year follow-up: SMD 0.906 (0.296 to 1.516) • 5-year follow-up: SMD 0.386 (-0.084 to 0.856) |
MF vs ACI: • 2- to 3-year follow-up: OR 0.439 (0.128 to 1.506) • 5-year follow-up: OR 0.847 (0.438 to 1.641) |
I2 (p) | • 1-year follow-up: 98% (p<.001) • 2-year follow-up: 96% (p<.001) • 5-year follow-up: 78% (p = .003) |
• 1-year follow-up: 98% (p<.001) • 2-year follow-up: 76% (p = .014) • 5-year follow-up: 99% (p<.001) |
• 2- to 3-year follow-up: 5% (p = .35) • 5-year follow-up: 0% (p = .82) |
Zamborsky et al. (2020)22 | |||
Total N | NR | NR | NR |
Pooled effect (95% CI) | MACI vs MF (positive value favors MACI): SMD 8.45 (1.62 to 15.28) | NR | MACI vs MF: • 2-year follow-up: RR 0.18 (0.02 to 1.63) • 5-year follow-up: RR 0.32 (0.03 to 3.02) |
I2(p) | NR | NR | NR |
Abraamyan et al. (2022)20 | |||
Total N | NR | NR | NR |
Pooled effect (p) | ACI/MACI vs MF: SMD -2.84 (p = .52) | ACI/MACI vs MF: SMD -2.46 (p = .53) | NR |
I2(p) | 93% (NR) | 91% (NR) | NR |
Angele et al. (2022)19 | |||
Range of N | NR | NR | NR |
Range of effect sizes | NR | NR | NR |
Dhillon et al. (2022)18 | |||
Range of N | NR | NR | 46 to 128 |
Range of effect sizes | Mean postoperative IKDC • ACI: 68.5 to 75.8 • MF: 61.8 to 66.6 Mean postoperative LKQ:a • ACI: 85.9 to 92.0 • MF: 69.0 to 78.8 |
NR | • ACI: 0% to 1.5% • MF: 2.5% to 8.3% |
Migliorini et al. (2022)17 | |||
Pooled effect (p) | MACI vs AMIC:c • Mean IKDC 71.5 vs 79.2 (p = .03) • Mean LKQ 65.7 vs 81.9 (p = .02) • Mean TAS 4.7 vs 4.4 (p = .2) |
NR | NR |
I2 (p) | NR | NR | NR |
ACI: autologous chondrocyte implantation; CI: confidence interval; IKDC: International Knee Documentation Committee; KOOS: Knee Injury and Osteoarthritis Outcome Score; LKQ: Lysholm Knee Questionnaire; MACI: matrix-induced autologous chondrocyte implantation; MF: microfracture; NMD: network mean difference; NR: not reported; OAT: osteochondral autograft transfer; OR: odds ratio; RR: risk ratio; SMD: standardized mean difference; TAS: Tegner activity score.
a One included study reported LKQ as mean improvement from baseline (4.9 with ACI vs 3.5 with MF).
c Time at which outcome was assessed was not reported in systematic review; comparison was by t-test of pooled extracted values for each group.
Autologous Chondrocyte Implantation and Matrix-Induced Autologous Chondrocyte Implantation for Osteochondritis Dissecans
A systematic review by Sacolick et al. (2019) examined the patient-reported outcomes, complication rates, and failure rates of autologous chondrocyte implantation and matrix-induced autologous chondrocyte implantation for osteochondritis dissecans in adults.27 Nine clinical studies were assessed (type not specified), with 179 (> 200 lesions) patients aged 18 to 49 years (mean, 27.6 years). Follow-up ranged from 6.5 months to 10 years. Results of patient-reported outcomes showed that 85% of patients reported excellent or good outcomes. All patient-reported outcome measures used across the studies (International Knee Documentation Committee Form, Lysholm Knee Questionnaire, EuroQol Visual Analog Scale, Cincinnati Rating System, and the Tegner Activity Scale) reported statistically significant improvements from preoperative to final follow-up (p-values not reported). Of the studies that reported complication and failure rates for autologous chondrocyte implantation/matrix-induced autologous chondrocyte implantation, 23 (15.7%) of 146 patients reported complications, and the failure rate was 8.2%. Unplanned reoperations were necessary for 20.5% of patients. The study results showed that autologous chondrocyte implantation/matrix-induced autologous chondrocyte implantation had the best outcomes for active young males with small lesions. Older adults and less active individuals, as well as those with lesions > 6 cm2, did not fare as well. A limitation of this review was its lack of randomized trials with controls to compare to autologous chondrocyte implantation/matrix-induced autologous chondrocyte implantation.
Randomized Controlled Trials
In 2017, first-generation autologous chondrocyte implantation with injection of chondrocytes under a collagen cover (sometimes called second-generation autologous chondrocyte implantation) was phased out and replaced with matrix-induced autologous chondrocyte implantation. Three RCTs were identified specifically on matrix-induced autologous chondrocyte implantation.
Matrix-Induced Autologous Chondrocyte Implantation Versus Autologous Chondrocyte Implantation
Bartlett et al. (2005) reported on a randomized comparison between matrix-induced autologous chondrocyte implantation and autologous chondrocyte implantation with a collagen cover in 91 patients.28 Overall, results were comparable for both treatments. The modified Cincinnati Knee Rating System score improved by 17.6 points in the autologous chondrocyte implantation group and by 19.6 points in the matrix-induced autologous chondrocyte implantation group (p = .32). Visual analog scale scores improved from 6.0 to 4.3 in the autologous chondrocyte implantation group and from 6.0 to 4.1 in the matrix-induced autologous chondrocyte implantation group. Factors associated with worse clinical outcomes were a failed prior procedure, duration of symptoms, and patient age. Second-look arthroscopy at 1 year for 42 patients showed excellent-to-good International Cartilage Repair Society scores in 79.2% of autologous chondrocyte implantation and in 66.6% of matrix-induced autologous chondrocyte implantation patients (p = .3). The authors did not report whether the study was adequately powered for this comparison. Histology from 14 autologous chondrocyte implantation and 11 matrix-induced autologous chondrocyte implantation patients showed similar percentages of hyaline-like cartilage (42.9% autologous chondrocyte implantation, 36.4% matrix-induced autologous chondrocyte implantation).
Matrix-Induced Autologous Chondrocyte Implantation Versus Microfracture
A randomized, open-label noninferiority phase 3 trial by Niemeyer et al. (2019) compared MACI using spheroid technology (n = 52) to MF (n = 50) in patients with focal cartilage defects of the knee between 1 and 4 cm2.29 The primary outcome was overall KOOS score at 2-year follow-up in the intention-to-treat population (comprising randomization patients who underwent either procedure and completed the baseline KOOS evaluation). In the primary analysis, the between-group difference in mean KOOS score was 6.1 favoring the autologous chondrocyte implantation group (p < .0001 for noninferiority). The authors reported no difference in overall incidence of adverse events between groups or in adverse events categorized by organ system. In an updated analysis at 60 months, the mean between-group difference in improvement in overall KOOS score from baseline was 6.7 favoring the autologous chondrocyte implantation group, with noninferiority maintained; the authors stated that the difference in improvement represented clinical superiority of autologous chondrocyte implantation.30
The SUMMIT trial was the pivotal, industry-sponsored, multicenter randomized open-label trial; it was reported by Saris et al. (2014) and compared matrix-induced autologous chondrocyte implantation with microfracture for larger cartilage defects (≥ 3 cm2), which typically fare worse than smaller lesions when treated with microfracture.31, Patients (N = 144) included had at least 1 symptomatic grade III or IV focal cartilage defect on the femoral condyles or trochlea, a stable knee, an intact or partial meniscus, and a moderate-to-severe KOOS pain value (< 55). Average lesion size was 4.8 cm2 (range, 3 to 20 cm2), and 34.6% of patients had undergone a prior marrow stimulation procedure. At 2-year follow-up, the matrix-induced autologous chondrocyte implantation group had significantly better subscores for KOOS pain (coprimary outcome; difference, 11.76; p < .001) and function in sport and recreation (coprimary outcome; difference, 11.41; p = .16) as well as the other KOOS subscales (function in daily living, knee-related quality of life, other symptoms). With response to treatment defined as a 10-point improvement in both the KOOS pain and function subscales, significantly more patients in the matrix-induced autologous chondrocyte implantation group responded to treatment (87.5%) than in the microfracture group (68.1%; p = .016). There were no significant differences between groups for cartilage repair, as measured by second-look arthroscopy, biopsy, or magnetic resonance imaging (MRI).
Brittberg et al. (2018) reported on a 5-year follow-up of the SUMMIT trial.32 Five years post-procedure, the KOOS pain and function score was still significantly better, both clinically and statistically, for matrix-induced autologous chondrocyte implantation than for microfracture (p = .022). Changes from baseline to year 5 were also higher for matrix-induced autologous chondrocyte implantation than microfracture for activities of daily living (p = .007), quality of life (p = .070), and other symptoms (p = .078). Over 5 years, 4 patients (1 matrix-induced autologous chondrocyte implantation, 3 microfractures) had treatment failures. The proportion of patients who required subsequent surgical procedures was similar in the 2 groups (10.8% in matrix-induced autologous chondrocyte implantation and 9.5% in microfracture). Limitations were potential bias from allowing participants to choose whether to continue with the extended study. In addition, the SUMMIT study was not blinded. However, the use of standardized surgical and rehabilitation procedures, validated clinical outcome instruments, and consistent outcomes among the multiple investigators strengthened the study.
Basad et al. (2010) reported on a small randomized trial that compared matrix-induced autologous chondrocyte implantation (n = 40) with microfracture (n = 20) in patients who had a single posttraumatic chondral defect between 4 and 10 cm2.33, Both groups improved at the 2-year follow-up, with a significant advantage of matrix-induced autologous chondrocyte implantation over microfracture on the Lysholm Knee Score (92 vs. 69, p = .005), Tegner Activity Score (4 vs. 3, p = .04), and International Cartilage Repair Society patient (p = .03) and International Cartilage Repair Society surgeon (p = .02) scores. Patients treated with matrix-induced autologous chondrocyte implantation from this trial, along with newly enrolled patients (n = 65), were followed for 5 years.34 However, the rate of follow-up decreased from 93.8% at 24 months to 38.5% at 60 months, limiting interpretation of the 5-year results. Twelve (18.5%) patients developed symptoms between 6 and 36 months such as pain, locking, crepitus, or recurrent effusion. Arthroscopy of these 12 showed partial disintegration of regenerated tissue (n = 5), subchondral edema (n = 2), graft fibrillation (n = 4), and progression to osteoarthritis (n = 1). All 12 underwent additional procedures, including osteochondral autograft transfer and microfracture, with good results.
Observational Studies
A variety of issues have been addressed with observational studies on autologous chondrocyte implantation or matrix-induced autologous chondrocyte implantation, including combination treatment with meniscal allograft, the durability of the procedure, realignment procedures performed in combination with autologous chondrocyte implantation, comparison of tibiofemoral defects and patellar defects, and influence of prior marrow stimulation.
Tibiofemoral Versus Patellofemoral Lesions
Fewer data are available on matrix-induced autologous chondrocyte implantation for patellofemoral lesions, but comparative observational studies have suggested outcomes that do not differ substantially from those using matrix-induced autologous chondrocyte implantation for tibiofemoral lesions.
Systematic Reviews
Schuette et al. (2017) published a systematic review of mid- to long-term clinical outcomes from use of matrix-induced autologous chondrocyte implantation in the knee.35 They included 10 studies (2 level I, 1 level II, 1 level III, 6 level IV studies), with a total of 442 tibiofemoral and 136 patellofemoral lesions/patients and follow-up of at least 5 years, published through September 2016. Four of the studies used the type I and III collagen matrix, 5 used Hyalograft C, and 1 used both. The 2 level I studies compared early with late weight-bearing following matrix-induced autologous chondrocyte implantation. Individual study quality was rated as good to fair, with an average rating of fair. Clinical outcomes, weighted for age and defect size, improved from baseline to latest follow-up. At follow-up the failure rate was 12.4% (3 studies, N = 145 ; range, 3.2% to 21.6%) for tibiofemoral joints and 4.7% (4 studies, N = 106 ; range, 0% to 50%) for patellofemoral joints (p = .037). The highest failure rates were reported in studies with the largest lesions and the longest follow-up.
One of the studies included in the Schuette et al. (2017) systematic review, Meyerkort et al. (2014)36,, was a prospective cohort of 23 patients who were treated with matrix-induced autologous chondrocyte implantation for patellofemoral lesions. The mean defect size was 3.5 cm2, and 9 (39%) of the patients underwent concurrent patellofemoral realignment procedures. At the 5-year follow-up, MRI indicated an intact appearance in most grafts, with graft height of more than 50% of the surrounding cartilage in 82% of patients. Patient-reported outcomes, measured with the KOOS and 36-Item Short Form Health Survey (SF-36), improved significantly compared with preoperative scores. The increase in distance walked in 6 minutes was statistically significant (p<.001) but modest (from 570 to 590 m). Graft hypertrophy was detected in 3 (13%) patients by MRI but symptoms were considered sufficient to merit debridement in only 1 (4.3%) patient.
A report by Zak et al. (2012)37, was also included in the Schuette et al. (2017) review. Zak et al. (2012) evaluated return to sports at 5 years in 70 patients who had matrix-induced autologous chondrocyte implantation, 15 of whom had matrix-induced autologous chondrocyte implantation in the patellofemoral joint. Significant improvements in the KOOS function in sport and recreation, Noyes grading system, and Tenger Activity Score scores were reported between presurgery and follow-up. Patients with 2 lesions had worse outcomes than patients with a single tibiofemoral lesion but there were no significant differences in outcomes between the tibiofemoral and patellofemoral groups.
Nonrandomized Comparative Studies
Three studies assessed in the systematic review were reported by Ebert et al. (2017) and colleagues.38,39,40 Ebert et al. (2017) reported on a comparative study with 24-month follow-up.41 They evaluated 194 patients with lesions on the medial or lateral femoral condyle (n = 127), patella (n = 35), or trochlea (n = 32). There were no significant differences between groups in demographics, defect size, prior injury, or surgical history. Patient-reported outcome measures, including the KOOS, visual analog scale for pain, SF-36, and satisfaction scores, were collected by an independent assessor. Most clinical scores were similar preoperatively except for the KOOS function in daily living and quality of life subscales, which were worse in the combined patella and trochlea group. Patellofemoral malalignment was corrected when indicated. Postoperative scores on the KOOS function in daily living, knee-related quality of life, and function in sport and recreation were significantly higher in the tibiofemoral group but both groups improved over time. Graft hypertrophy assessed using MRI was more frequent in the tibiofemoral group (32.1%) than the patellofemoral group (10.4%). All lesions with hypertrophy were asymptomatic at the 24-month follow-up.
Combined Meniscal Allograft and Cartilage Repair
The systematic review by Harris et al. (2011) evaluated combined meniscal allograft transplantation and cartilage repair/restoration.42 Six level IV studies (case series) with a total of 110 patients were included. Patients underwent meniscal allograft transplantation with autologous chondrocyte implantation (n = 73), osteochondral allograft (n = 20), osteochondral autograft transfer (n = 17), or microfracture (n = 3). All studies showed improvements in clinical outcomes at final follow-up compared with the preoperative baseline. Outcomes were also compared with historical outcomes of each procedure performed in isolation. Four of the 6 studies found outcomes equivalent to procedures performed in isolation, while 2 found that outcomes with combined surgery were not as good as the historical controls. Across the 6 studies, 13 (12%) failures were reported; they included 11 isolated meniscal allograft transplantation failures, 1 combined meniscal allograft and autologous chondrocyte implantation failure, and 1 isolated autologous chondrocyte implantation failure. Three knees with failed meniscal allograft transplantation were converted to total knee arthroplasty. Nearly 50% of patients underwent 1 or more subsequent surgeries after combined meniscal allograft transplantation and cartilage repair/restoration procedures.
Durability and Effects of Realignment and Prior Procedures
Seiferth et al. (2022) performed a propensity-score matched analysis of 730 patients who underwent autologous chondrocyte implantation for cartilage repair of the knee following previous unspecified knee surgery (matched to 690 similar patients who did not have a knee surgery history prior to autologous chondrocyte implantation).43 Propensity scoring incorporated age, sex, body mass index, duration of symptoms, smoking status, size, International Cartilage Regeneration & Joint Preservation Society grade, localization, and cause of the defect, and integrity of the corresponding joint service. The authors found that patients undergoing autologous chondrocyte implantation with history of prior knee surgery had significantly lower KOOS scores than those without prior knee surgery at 6 months, but no difference was identified between groups at subsequent follow-up ranging from 1 to 3 years. The authors performed a similar analysis in patients with (n = 317) and without (n = 254) history of prior treatment of the chondral site; in this analysis, mean KOOS scores were significantly lower in patients undergoing autologous chondrocyte implantation with history of failed chondral treatment compared to those without history of failed chondral treatment at all timepoints ranging from 6 to 36 months.
Andriolo et al. (2017) performed a systematic review of literature that reported on the failure rate of autologous chondrocyte implantation or matrix-induced autologous chondrocyte implantation.44 Fifty-eight studies were included: 4 RCTs, 6 comparative observational studies, and 48 case series (N = 4294 ). At a mean follow-up of 86 months, the failure rate was 14.9% (range, 0% to 43%) and the mean time of failure was 26 months in the 19 studies reporting time to failure. However, there was high heterogeneity in how failure rates were defined in selected studies.
A study by Nawaz et al. (2014) evaluated functional outcomes and survival rates for autologous chondrocyte implantation (periosteal or collagen membrane-covered) and matrix-induced autologous chondrocyte implantation in 869 patients.45 For the group as a whole, graft survival was estimated by Kaplan-Meier analysis to be 78.2% (95% CI, 74.9% to 81.1%) at 5 years and 50.7% (95% CI, 45.2% to 55.9%) at 10 years. Graft survival did not differ between the first- and second-generation (matrix-induced autologous chondrocyte implantation) procedures. Functional and pain scores were significantly better in the matrix-induced autologous chondrocyte implantation group but this finding might have been confounded by the shorter follow-up with the newer technique.
Minas et al. (2014) prospectively followed 210 autologous chondrocyte implantation-treated patients (362 grafts) for at least 10 years.46 Malalignment, patellar maltracking, and meniscal or ligamentous deficiency had also been corrected as needed. At a mean follow-up of 12 years, 53 (25%) patients had graft failure. For the 157 patients who had successful grafts, functional outcomes were significantly improved from baseline to follow-up, as measured by the Western Ontario and McMaster Universities Index, Knee Society Score for knee and function, and SF-36 (all p < .001). Graft survival was significantly longer in patients with complex versus salvage-type lesions (p = .03), with concomitant high tibial osteotomy versus no high tibial osteotomy (p = .01), and with primary autologous chondrocyte implantation versus autologous chondrocyte implantation after a prior marrow stimulation procedure (p = .004). For example, primary graft survival was 79% compared with 44% for defects previously treated with microfracture.
A 3-fold increase in autologous chondrocyte implantation failure rate after previous treatment with marrow stimulation techniques was reported by Minas et al. (2009) in a cohort of 321 patients with more than 2 years of follow-up.47 Independent analysis showed a failure rate of 8% (17/214) of joints without prior marrow stimulation of the lesion, compared with 26% (29/111) of joints that had not. The Nawaz et al. (2014) study of 869 patients treated with autologous chondrocyte implantation or matrix-induced autologous chondrocyte implantation (described above) found that overall graft survival was 78.2% at 5 years and 50.7% at 10 years using Kaplan-Meier analysis.45, Graft failure was 5 times more likely with a previously treated lesion (< 25% survival at 12 years) compared with a previously untreated lesion (> 75% survival at 12 years) (hazard ratio, 5.33; 95% CI, 4.07 to 6.99; p < .001). Other factors affecting survival were graft location and the severity of degenerative changes.
Graft Hypertrophy
Ebert et al. (2015) reported on graft hypertrophy (tissue overgrowth) at 24 months after matrix-induced autologous chondrocyte implantation in a consecutive series of 180 patients.48 Patients were assessed clinically using the KOOS and underwent MRI at 3, 12, and 24 months post-matrix-induced autologous chondrocyte implantation. Seventeen (9.4%) grafts had failed by 24 months. Three grafts were hypertrophic at 3 months but the hypertrophy had resolved by 24 months. At 24 months, 47 (26.1%) grafts were hypertrophic. KOOS did not differ between patients with hypertrophic grafts and those with normal tissue infill. Longer follow-up is needed to evaluate whether tissue growth continues and to determine the effect of the hypertrophy on graft stability.
Section Summary: Autologous Chondrocyte Implantation for Treatment of Focal Articular Cartilage Lesion(s) of the Knee
The evidence on autologous chondrocyte implantation for the treatment of focal articular cartilage lesions of the knee includes meta-analyses, systematic reviews, RCTs, and longer-term observational studies. For large lesions, autologous chondrocyte implantation results in better outcomes than microfracture, particularly in the long term. Studies comparing autologous chondrocyte implantation with osteochondral autograft transfer have shown similar outcomes with smaller lesions, and improved outcomes with autologous chondrocyte implantation when a defect is greater than 4 cm2. In 2017, first-generation autologous chondrocyte implantation was replaced with a preparation that seeds the chondrocytes onto a bioresorbable collagen sponge (matrix-induced autologous chondrocyte implantation). Studies to date have not shown improved outcomes compared with first-generation autologous chondrocyte implantation. There is some evidence of an increase in implant hypertrophy (overgrowth) at 2 years, particularly on the femoral condyles that may exceed that of the collagen membrane-covered implant. Long-term studies with a larger number of patients are needed to determine whether hypertrophy impacts graft survival. Matrix-induced autologous chondrocyte implantation for patellar lesions has been evaluated in a systematic review and a nonrandomized comparative study. The included studies reported outcomes that did not differ substantially from those using matrix-induced autologous chondrocyte implantation for tibiofemoral lesions. Observational studies have indicated that a prior cartilage procedure may negatively impact the success of autologous chondrocyte implantation, realignment procedures improve the success of autologous chondrocyte implantation for patellar lesions, and autologous chondrocyte implantation combined with meniscal allograft results in outcomes similar to either procedure performed alone.
Autologous Chondrocyte Implantation for Joints Other Than the Knee
Clinical Context and Therapy Purpose
The purpose of autologous chondrocyte implantation in individuals with focal articular cartilage lesions of joints other than the knee is to provide a treatment option that is an alternative to or an improvement on existing therapies.
The following PICO was used to select literature to inform this review.
Populations
The relevant population of interest is individuals with focal articular cartilage lesions of joints other than the knee.
Interventions
The treatment being considered is autologous chondrocyte implantation. The first stage of implantation includes arthroscopy to obtain a biopsy of healthy articular cartilage and the second stage is the arthrotomy.
Comparators
The comparators of interest are marrow stimulation or osteochondral autograft.
Outcomes
The outcomes of interest are symptoms, change in disease status, morbid events, functional outcomes, and quality of life.
Positive outcomes include easy implantation, reduction in surgical morbidity, no need to harvest other tissues, enhancement of cell proliferation and maturation, maintenance of phenotype, and integration with surrounding tissues.
Negative outcomes include hypertrophy of the transplant, disturbed fusion of the regenerative and healthy surrounding cartilage, inadequate regenerative cartilage, and delamination.
The existing literature evaluating autologous chondrocyte implantation has varying lengths of follow-up, ranging from 6 to 120 months. A minimum of 1 year of follow-up would be considered necessary to demonstrate efficacy.
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
Systematic Reviews
Two systematic reviews with meta-analysis have evaluated autologous chondrocyte implantation for patients with focal articular cartilage lesions of the talus; the studies included, characteristics of the systematic reviews, and key findings are outlined in Tables 5, 6, and 7, respectively.
A 2022 systematic review with Bayesian network meta-analysis by Migliorini et al. evaluated 13 studies with minimum 18-month follow-up comparing surgical interventions for chondral defects of the talus.49 The studies comprised 521 patients, with median follow-up of 47.8 months; most studies, including all that evaluated autologous chondrocyte implantation, were retrospective, with 1 RCT and 2 prospective cohort trials included. The authors found that cell-free autologous membrane-induced chondrogenesis produced the highest American Orthopedic Foot and Ankle Society (AOFAS) scores and produced the lowest rates of failure. However, the timeframe for reporting of AOFAS score and other endpoints was not described, and funnel plots for all reported outcomes suggest the presence of publication bias.
Hu et al. (2021) reported a systematic review with meta-analysis of studies published through November 2020.50 The authors included a total of 23 case series (N = 458) with a mean duration of 12 to 154.8 months. In 6 studies, periosteum-covered autologous chondrocyte implantation was applied while 17 studies used second-generation matrix-induced autologous chondrocyte implantation. Results demonstrated an 89% success rate AOFAS score > 80) with autologous chondrocyte implantation. Furthermore, AOFAS scores significantly improved after treatment. Twelve of the case series in Hu et al. (2021) overlap with Niemeyer et al. (2012), described below.
A meta-analysis by Niemeyer et al. (2012) evaluated 16 studies (N = 213).51 All were case series, with a mean sample size of 13 patients (range, 2 to 46 patients) and mean follow-up of 32 months (range, 6 to 120 months). Most series were prospective. In 6 studies, periosteum-covered autologous chondrocyte implantation was applied while 10 studies used second-generation matrix-induced autologous chondrocyte implantation. Nine different methods were used to evaluate preoperative and postoperative clinical function, with the most common being the AOFAS score. Overall clinical success rate, defined as the percentage of good and excellent results, was 89.9% (range, 50% to 100%). Change in AOFAS scores was not reported.
Table 5. Comparison of Trials/Studies Included in Systematic Reviews of Autologous Chondrocyte Implantation for Cartilage Repair of the Talus
Study | Niemeyer et al. (2012)51 | Hu et al. (2021)50 | Migliorini et al. (2022)49 |
Giannini (2001) | ⚫ | ⚫ | |
Koulalis (2002) | ⚫ | ||
Cherubino (2003) | ⚫ | ||
Dorotka (2004) | ⚫ | ⚫ | |
Giannini (2005) | ⚫ | ⚫ | |
Whittaker (2005) | ⚫ | ⚫ | |
Baums (2006) | ⚫ | ⚫ | |
Gobbi (2006) | ⚫ | ||
Caumo (2007) | ⚫ | ⚫ | |
Giannini (2008) | ⚫ | ⚫ | |
Thermann (2008) | ⚫ | ||
Giannini (2009) | ⚫ | ⚫ | |
Nam (2009) | ⚫ | ⚫ | |
Quirbach (2009) | ⚫ | ||
Schneider (2009) | ⚫ | ⚫ | |
Giza (2010) | ⚫ | ⚫ | |
Lee (2010) | ⚫ | ⚫ | |
Battaglia (2011) | ⚫ | ||
Apprich (2012) | ⚫ | ||
Domayer (2012) | ⚫ | ||
Haene (2012) | ⚫ | ||
Lee (2013) | ⚫ | ||
Haleem (2014) | ⚫ | ||
Kwak (2014) | ⚫ | ||
Yoon (2014) | ⚫ | ||
Buda (2015) | ⚫ | ||
Ahmad (2016) | ⚫ | ||
Gül (2016) | ⚫ | ||
Guney (2016) | ⚫ | ||
D'Ambrosi (2017) | ⚫ | ||
Desando (2017) | ⚫ | ||
Chan (2018) | ⚫ | ||
Pagliazzi (2018) | ⚫ | ||
Park (2018) | ⚫ | ||
Kreulen (2018) | ⚫ | ||
Shimozono (2018) | ⚫ | ||
Shimozono (2018) | ⚫ | ||
Becher (2019) | ⚫ | ||
López-Alcorocho (2019) | ⚫ | ||
Lenz (2020) | ⚫ |
Table 6. Systematic Review and Meta-Analysis Characteristics
Study | Dates | Studies | Participants | Mean N (Range) | Design | Duration |
Niemeyer et al. (2012)51 | 1994 to February 2011 | 16 | N = 213 patients undergoing autologous chondrocyte implantation or matrix-induced autologous chondrocyte implantation for lesions of the talus. | 13 (2 to 46) | Case series | Follow up, 32 months (6 to 120) |
Hu et al. (2021)50 | Through November 2020 | 23 | N = 458 patients undergoing autologous chondrocyte implantation for lesions of the talus. | Mean not provided (7 to 46) |
Case series | 12 to 154.8 months |
Migliorini et al. (2022)49 | 2006 to 2018 | 13 | N = 521 patients undergoing AMIC, MACI, MF, mosaicplasty, or OAT for chondral lesions of the talus. | Mean not provided (20 to 94) | 1 RCT, 2 prospective cohort studies, 10 retrospective studies | 22.3 to 113.8 months |
AMIC: autologous membrane-induced chondrogenesis; MACI: matrix-induced autologous chondrocyte implantation; MF: microfracture; OAT: osteochondral autograft transplant; RCT: randomized controlled trial.
Table 7. Systematic Review & Meta-Analysis Results
Study | Clinical Success Rate | AOFAS Score |
Niemeyer et al. (2012)51 | ||
Total N | 213 | |
Pooled effect (95% CI) | 89.9 (50 to 100) | NR |
Hu et al. (2021)50 | ||
Total N | 458 | 458 |
Pooled effect (95% CI) | 89% (85 to 92) | 86.33% (83.33 to 89.33) |
p-value | < .001 | < .001 |
Migliorini et al. (2022)49 | ||
Total N | NR | NR |
Pooled effect (95% CI) | NR | SMD: • MACI: -14.03 (-21.99 to -6.07) • AMIC: 11.27 (-2.12 to 24.67) • MF: -22.68 (-33.77 to -11.59) • Mosaicplasty: -15.54 (-23.44 to -7.63) • OAT: -14.32 (-21.69 to -6.95) |
AMIC: autologous membrane-induced chondrogenesis; AOFAS: American Orthopedic Foot and Ankle Society; CI: confidence interval; MACI: matrix-induced autologous chondrocyte implantation; MF: microfracture; NR: not reported; OAT: osteochondral autograft transplant; SMD: standardized mean difference.
Shimozono et al. (2017) reported a systematic review without meta-analysis of scaffolds-based therapy for osteochondral lesions of the talus and selected articles published through January 2017.52 Seven studies were found on the use of matrix-induced autologous chondrocyte implantation and 5 studies were found on Hyalograft C. All studies were case series; the quality of evidence was rated as fair in 2 studies and poor in the remaining 11 studies. Sample sizes ranged from 10 to 46 patients (mean, 22 patients) and follow-up ranged from 21 to 87 months (mean, 46 months). Twelve of 13 studies reported preoperative and postoperative AOFAS scores; the mean AOFAS score improved from 59 to 87.
Observational Studies
Krueger et al. (2023) reported a retrospective case series of 36 consecutive patients who underwent autologous chondrocyte implantation for cartilage defects of the acetabulum.53 With mean follow-up of 29.9 months (minimum 24 months), mean modified Harris Hip Score improved significantly between pre-operative baseline and last follow-up (p = .001), and mean patient-reported Subjective Hip Value improved from 51.5% at pre-operative baseline to 87.4% postoperatively (value of 100% indicates an unimpaired hip; p = .001). The authors stated no serious intraoperative complications or postoperative adverse events were observed.
Section Summary: Autologous Chondrocyte Implantation for Joints Other Than the Knee
The evidence on use of autologous chondrocyte implantation for joints other than the knee includes case series, systematic reviews of case series, and a network meta-analysis of prospective and retrospective studies (no prospective studies evaluated autologous chondrocyte implantation). The most commonly reported use of autologous chondrocyte implantation is for the talus; one case series describes use for the acetabulum. Comparative trials are needed to determine whether autologous chondrocyte implantation improves outcomes for lesions of the talus and other joints.
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.
2015 Input
In response to requests, input was received from 2 physician specialty societies (6 reviewers) and 4 academic medical centers while this policy was under review in 2015. Input was generally supportive of the use of autologous chondrocyte implantation for large patellar lesions, although the degree of support varied. Reviewers indicated that outcomes were improved when realignment procedures were performed concurrently with autologous chondrocyte implantation of the patella and that success rates were lower when using autologous chondrocyte implantation after a prior microfracture. Most reviewers recommended that a prior surgical procedure not be required for lesions greater than 4 cm2.
2011 Input
In response to requests, input was received from 2 physician specialty societies and 3 academic medical centers while this policy was under review in 2011. Input was generally in agreement with the stated criteria for autologous chondrocyte implantation, except the following: input was mixed on the requirement for an inadequate response to a prior surgical procedure and the requirement for an absence of meniscal pathology. Input was also mixed on the investigational status of autologous chondrocyte implantation in patellar and talar joints.
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 Orthopaedic Surgeons
In its 2010 guidelines on the diagnosis and treatment of osteochondritis dissecans, the American Academy of Orthopaedic Surgeons did not recommend for or against a specific cartilage repair technique in symptomatic skeletally immature or mature patients with an unsalvageable osteochondritis dissecans lesion.54 This finding of insufficient evidence was based on a systematic review that found 4 level IV studies addressing cartilage repair techniques for an unsalvageable osteochondritis dissecans lesion. Because each level IV article used different techniques, different outcome measures, and differing lengths of follow-up, the Academy deemed the evidence for any specific technique inconclusive.
National Institute for Health and Care Excellence
In 2018, NICE updated its 2005 guidance on the use of autologous chondrocyte implantation.55, The NICE recommendations are stated below:
"... as an option for treating symptomatic articular cartilage defects of the femoral condyle and patella of the knee (International Cartilage Repair Society grade III or IV) in adults, only if:
- the person has not had previous surgery to repair articular cartilage defects;
- there is minimal osteoarthritic damage to the knee (as assessed by clinicians experienced in investigating knee cartilage damage using a validated measure for knee osteoarthritis); and
- the defect is over 2 cm2."
U.S. Preventive Services Task Force Recommendations
Not applicable
Ongoing and Unpublished Clinical Trials
Some currently ongoing trials that might influence this review are listed in Table 8.
Table 8. Summary of Key Trials
NCT No. | Trial Name | Planned Enrollment | Completion Date |
Ongoing | |||
NCT04785092 | All Autologous Cartilage Regeneration in the Treatment of the Knee Cartilage Defects | 20 | March 2024 |
NCT03219307 | Safety and Efficacy of NOVOCART 3D in the Treatment of Articular Cartilage Defects Following Failure on Microfracture | 30 | Dec 2023 |
NCT01656902a | A Prospective Randomized Controlled Multicenter Phase-III Clinical Study to Evaluate the Safety and Effectiveness of NOVOCART® 3D Plus Compared to the Standard Procedure Microfracture in the Treatment of Articular Cartilage Defects of the Knee | 26 3 | June 2023 |
NCT04744402 | A Multi-Center, Active-Controlled, Open-Label, Phase 2 Trial to Compare the Efficacy and Safety of CartiLife®, and Microfracture for Patients With Articular Cartilage Defects in the Knee | 50 | Dec 2023 |
NCT01957722a | A Phase 3, Prospective, Randomized, Partially Blinded Multi-Center Study to Measure the Safety and Efficacy of NOVOCART 3D Compared to Microfracture in the Treatment of Articular Cartilage Defects | 233 | Dec 2024 |
NCT05651997 | Randomized Study Comparing Two Methods for the Treatment of Large Chondral and Osteochondral Defects of the Knee: Augmented Microfracture Technique vs 3rd Generation of ACI | 80 | June 2028 |
NCT05402072a | Autologous MatRix-Induced ChondrogenEsis ComPared With Microfracture for Focal ArtIcular CaRtilage Damage of the Hip (REPAIR): A Pilot Randomized Controlled Trial | 30 | Jan 2026 |
NCT05328674 | Clinical and Comparative Evaluation of the Treatment Results of Arthroscopic Reconstruction of Cartilage Defects in the Knee Joint With the Use of Autogenous Cartilage Graft with PRP GF (Platelet-rich Plasma With Growth Factors) | 60 | June 2022 |
NCT: national clinical trial.
a Denotes industry-sponsored or cosponsored trial.
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Coding Section
Codes | Number | Description |
CPT | 29870-29887 | Code range, arthroscopy of the knee |
27412 | Autologous chondrocyte implantation, knee | |
ICD-9 Procedure | 80.26 | Arthroscopy of the knee |
80.16 | Arthrotomy of the knee | |
ICD-9 Diagnosis | 715.16 | Osteoartrosis, loclized, primary, lower leg |
715.26 | Osteoarthrosis, localized, secondary, lower leg | |
715.36 | Osteoarthrosis, localized, not specified whether primary or secondary, lower leg | |
715.96 | Osteoarthrosis, unspecified whether generalized or localized, lower leg | |
716.16 | Traumatic arthropathy, lower leg | |
718.06 | Articular cartilage disorder, lower leg | |
718.86 | Other joint derangement, lower leg | |
719.86 | Other specified disorders of joint, lower leg | |
732.7 | Osteochondritis dissecans | |
733.90 | Other unspecifed disorder of bone and cartilage | |
959.7 | Injury, knee, leg, ankle, and foot | |
HCPCS | J7330 | Autologous cultured chondrocytes, implant |
S2112 | Arthroscopy, knee, surgical, for harvesting of cartilage (chondrocyte cells) | |
ICD-10-CM (effective 10/01/15) | M17.0-M17.12 | Osteoarthritis of knee primary code range |
M17.4-M17.5 | Osteoarthritis of knee secondary code range | |
M17.9 | Osteoarthritis of knee unspecified code range | |
M12.561-M12.569 | Traumatic arthropathy, knee code range | |
M23.90-M23.92 | Unspecified, internal derangement of knee code range | |
M23.8x1-M23.8x9 | Other internal derangement of knee code range | |
M25.861-M25.569 | Other specified joint disorder, knee code range | |
M93.261-M93.269 | Osteochondritis dissecans knee code range | |
M89.8x6 | Other specified disorder of bone, lower leg | |
M94.8x6 | Other specified disorder of cartilage, lower leg | |
S89.90-S89.92 | Unspecified injury of lower leg code range | |
S99.811-S99.929 | Other specified injures of ankle and foot code range | |
ICD-10-PCS (effective 10/01/15) | 0SJC4ZZ, 0SJD4ZZ | Surgical, lower joints, inspection, knee joint, percutaneous endoscopic, code by side (right or left) |
0S9C0ZZ, 0S9D0ZZ | Surgical, lower joints, dranage, knee joint, open code by side (right or left) | |
0SUC07Z, 0SUD07Z | Surgical, lower joints, supplement, knee joint, open, autologous tissue supplement, code by side (right or left) | |
0SUC47Z, 0SUD47Z | Surgical, lower joints, supplement, knee joint, percutaneous endoscopic, autologous tissue supplement, code by side (right or left) | |
Type of Service | Surgery | |
Place of Service | Inpatient |
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
Autologous Chondrocyte Implantation
Autologous Chondrocyte Transplantation
Chondrocyte Transplantation, Autologous
Matrix-Induced Autologous Chondrocyte Implantation
Transplantation, Autologous Chondrocyte
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,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 2013 Forward
12/05/2023 | Annual review, no change to policy intent. Updating description, guidelines, rationale and references |
12/02/2022 | Annual review, no change to policy intent. Updating rationale and references |
12/01/2021 |
Annual review, no change to policy intent. Updating rationale and references. |
12/01/2020 |
Annual review, no change to policy intent. Updating rationale and references. |
12/12/2019 |
Annual review, no change to policy intent. Updating references. |
12/13/2018 |
Annual review, no change to policy intent. Updating rationale and references. |
01/16/2018 |
Annual review, no change to policy intent. Updated policy verbiage removing language regarding matrix induced implantation with a revision of the rationale to focus on available products. Also updating background, description, regulatory status and references. |
12/05/2016 |
Annual review, no change to policy intent. |
12/2/2015 |
Annual review, removing the need for a prior surgical procedure as a requirement for medical necessity. Updated background, description, regulatory status, rationale and references. |
12/11/2014 |
Annual review, no change to policy intent. Added keywords and coding, updating rationale and references. |
12/11/2013 |
Annual review, Change title, update description, regulatory status, policy, guidelines, rationale and references. Added related policies and Benefit Applications. |