Orthopedic Applications of Stem Cell Therapy (Including Allografts and Bone Substitutes Used With Autologous Bone Marrow) - CAM 80152HB

Description 
Mesenchymal stem cells (MSCs) have the capability to differentiate into a variety of tissue types, including various musculoskeletal tissues. Potential uses of MSCs for orthopedic applications include treatment of damaged bone, cartilage, ligaments, tendons, and intervertebral discs.

For individuals who have cartilage defects, meniscal defects, joint fusion procedures, or osteonecrosis who receive stem cell therapy, the evidence includes small randomized controlled trials and nonrandomized comparative trials. Relevant outcomes are symptoms, morbid events, functional outcomes, quality of life, and treatment-related morbidity. Use of MSCs for orthopedic conditions is an active area of research. Despite continued research into the methods of harvesting and delivering treatment, there are uncertainties regarding the optimal source of cells and the delivery method. Studies have included MSCs from bone marrow, adipose tissue, peripheral blood, and synovial tissue. The largest body of evidence has evaluated the use of autologous MSCs, either concentrated or expanded in culture, for cartilage repair. This evidence includes small randomized and nonrandomized comparative trials with insufficient data to evaluate health outcomes. Also, expanded MSCs for orthopedic applications are not U.S. Food and Drug Administration-approved (concentrated autologous MSCs do not require agency approval). Overall, there is a lack of evidence that clinical outcomes are improved. The evidence is insufficient to determine the effects of the technology on health outcomes. 

Background 
MESENCHYMAL STEM CELLS
Mesenchymal stem cells (MSCs) are multipotent cells (also called multipotent stromal cells) that can differentiate into various tissues including organs, trabecular bone, tendon, articular cartilage, ligaments, muscle, and fat. MSCs are associated with the blood vessels within the bone marrow, synovium, fat, and muscle, where they can be mobilized for endogenous repair as occurs with the healing of bone fractures. Tissues, such as muscle, cartilage, tendon, ligaments, and vertebral discs, show limited capacity for endogenous repair because of the limited presence of the triad of functional tissue components: vasculature, nerves, and lymphatics. Orthobiologics is a term introduced to describe interventions using cells and biomaterials to support healing and repair. Cell therapy is the application of MSCs directly to a musculoskeletal site. Tissue engineering techniques use MSCs and/or bioactive molecules such as growth factors and scaffold combinations to improve the efficiency of repair or regeneration of damaged musculoskeletal tissues. 

Bone marrow aspirate is considered the most accessible source and, thus, the most common place to isolate MSCs for treatment of musculoskeletal disease. However, harvesting MSCs from bone marrow requires a procedure that may result in donor-site morbidity. Also, the number of MSCs in bone marrow is low, and the number and differentiation capacity of bone marrow-derived MSCs decreases with age, limiting their efficiency when isolated from older patients.

In vivo, the fate of stem cells is regulated by signals in the local 3-dimensional microenvironment from the extracellular matrix and neighboring cells. It is believed that the success of tissue engineering with MSCs will also require an appropriate 3-dimensional scaffold or matrix, culture conditions for tissue-specific induction, and implantation techniques that provide appropriate biomechanical forces and mechanical stimulation. The ability to induce cell division and differentiation without adverse effects, such as the formation of neoplasms, remains a significant concern. Given that each tissue type requires different culture conditions, induction factors (signaling proteins, cytokines, growth factors), and implantation techniques, each preparation must be individually examined.

Regulatory Status 
The FDA regulates human cells and tissues intended for implantation, transplantation, or infusion through the Center for Biologics Evaluation and Research, under Code of Federal Regulation, Title 21, parts 1270 and 1271. MSCs are included in these regulations.

The regulatory status of the stem cell or stem cell-containing products addressed in this review is summarized below.

Concentrated autologous MSCs do not require approval by the FDA. No products using engineered or expanded MSCs have been approved by the FDA for orthopedic applications.

The following products are examples of commercialized demineralized bone matrix (DBM) products. They are marketed as containing viable stem cells. In some instances, manufacturers have received communications and inquiries from the FDA related to the appropriateness of their marketing products that are dependent on living cells for their function. The following descriptions are from the product literature.

  • AlloStem® (AlloSource) is a partially demineralized allograft bone seeded with adipose-derived MSCs.
  • Map3® (RTI Surgical) contains cortical cancellous bone chips, DBM, and cryopreserved multipotent adult progenitor cells (MAPC®).
  • Osteocel Plus® (NuVasive) is a DBM combined with viable MSCs isolated from allogeneic bone marrow.
  • Trinity Evolution Matrix™ (Orthofix) is a DBM combined with viable MSCs isolated from allogeneic bone marrow.
  • Other products contain DBM alone and are designed to be mixed with bone marrow aspirate:
    • Fusion Flex™ (Wright Medical) is a dehydrated moldable DBM scaffold (strips and cubes) that will absorb autologous bone marrow aspirate;
    • Ignite® (Wright Medical) is an injectable graft with DBM that can be combined with autologous bone marrow aspirate.

A number of DBM combination products have been cleared for marketing by the FDA through the 510(k) process. FDA product code: MQV.

Tables 1 and 2 provide a representative sample of these products, differentiated by whether they must be mixed with autologous MSCs.

Table 1. Examples of Demineralized Bone Matrix Products Cleared by FDA that Do Not Require Mixing with Autologous MSCs

Product Matrix Type   Manufacturer or Sponsor Date Cleared 510(k) No.
Vitoss® Bioactive Foam Bone Graft Substitute Type I bovine collagen   Stryker Nov 2008 K083033
NanOss BVF-E Nanocrystalline hydroxyapatite   Pioneer Surgical Aug 2008 K081558
OrthoBlast® II Demineralized bone matrix putty and paste Human (mixed allograft donor-derived) cancellous bone chips   SeaSpine Sep 2007 K070751
DBX® Demineralized bone matrix putty, paste and mix Processed human (single allograft donor-derived) bone and sodium hyaluronate   Musculoskeletal Transplant Foundation Dec 2006 K053218
Formagraft™ Collagen Bone Graft Matrix Bovine fibrillary collagen   R and L Medical May 2005 K050789
DynaGraft® II Gel and Putty Processed human (mixed allograft donor-derived) bone particles   IsoTis Orthobiologics Mar 2005 K040419

FDA: U.S. Food and Drug Administration; MSCs: mesenchymal stem cells.

Table 2. Examples of Demineralized Bone Matrix Products Cleared by FDA that Require Mixing with Autologous MSCs

Product Matrix Type Manufacturer or Sponsor Date Cleared 510(k) No.
CopiOs® Bone Void Filler (sponge and powder disc) Type I bovine dermal collagen Kensey Nash May 2007 K071237
Integra MOZAIK™ Osteoconductive Scaffold-Putty Collagen matrix with tricalcium phosphate granules IsoTis OrthoBiologics Dec 2006 K062353

FDA: Food and Drug Administration; MSCs: mesenchymal stem cells.

In 2017, the FDA published "Regulatory Considerations for Human Cells, Tissues, and Cellular and Tissue-Based Products: Minimal Manipulation and Homologous Use" https://www.fda.gov/media/124138/download 

Human cells, tissues, and cellular and tissue-based products (HCT/P) are defined as human cells or tissues that are intended for implantation, transplantation, infusion, or transfer into a human recipient. If an HCT/P does not meet the criteria below and does not qualify for any of the stated exceptions, the HCT/P will be regulated as a drug, device, and/or biological product and applicable regulations and premarket review will be required.

An HCT/P is regulated solely under section 361 of the PHS Act and 21 CFR Part 1271 if it meets all of the following criteria:

"1) The HCT/P is minimally manipulated.
2) The HCT/P is intended for homologous use only, as reflected by the labeling, advertising, or other indications of the manufacturer’s objective intent.
3) The manufacture of the HCT/P does not involve the combination of the cells or tissues with another article, except for water, crystalloids, or a sterilizing, preserving, or storage agent, provided that the addition of water, crystalloids, or the sterilizing, preserving, or storage agent does not raise new clinical safety concerns with respect to the HCT/P.
4) Either: i) The HCT/P does not have a systemic effect and is not dependent upon the metabolic activity of living cells for its primary function OR
ii) The HCT/P has a systemic effect or is dependent upon the metabolic activity of living cells for its primary function, and: a) Is for autologous use; b) Is for allogeneic use in a first-degree or second-degree blood relative; or c) Is for reproductive use."

The FDA does not consider the use of stem cells for orthopedic procedures to be homologous use. In June 2019, the FDA issued a statement on a stem cell clinic permanent injunction and FDA's ongoing efforts to protect patients from risks of unapproved stem cell products.2

Policy
Mesenchymal stem-cell therapy is investigational and / or unproven and therefore considered NOT MEDICALLY NECESSARY for all orthopedic applications, including use in repair or regeneration of musculoskeletal tissue.

Allograft bone products containing viable stem cells, including but not limited to demineralized bone matrix (DBM) with stem cells, is investigational and/ or unproven and therefore considered NOT MEDICALLY NECESSARY for all orthopedic applications.

Allograft or synthetic bone graft substitutes that must be combined with autologous blood or bone marrow are investigational and/or unproven and therefore considered NOT MEDICALLY NECESSARY for all orthopedic applications.

Policy Guidelines
This policy does not address unprocessed allograft bone or products that do not require mixing with stem cells (product examples are shown in Tables 1 and 2 for informational purposes).

Benefit Application
BlueCard®/National Account Issues
The Regenexx™ procedure is currently performed in one location (Regenerative Sciences, Colorado). Therefore, requests may be made for an out-of-network facility.

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

To assess whether the evidence is sufficient to draw conclusions about the net health outcome of technology, 2 domains are examined: the relevance, and quality and credibility. To be relevant, studies must represent 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 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.

Cartilage Defects
Clinical Context and Therapy Purpose

The purpose of stem cell therapy is to provide a treatment option that is an alternative to or an improvement on existing therapies in patients with osteoarthritis (OA) or focal cartilage defects.

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

Populations
The relevant population of interest is individuals with OA or focal cartilage defects.

Interventions
The therapy being considered is treatment with mesenchymal stem cells (MSCs).

Comparators
Comparators of interest include conservative management with medication or hyaluronic acid (HA) injection, microfracture, and autologous chondrocyte implantation.

Outcomes
The general outcomes of interest are symptoms, morbid events, functional outcomes, QOL, and treatment-related morbidity (TRM). Specific scales may include the:

  • Knee Injury and Osteoarthritis Outcome Score (KOOS; 5 subscales with 0 – 100 scale).
  • Lysolm Knee Scale (LKS) score (0 – 100 scale).
  • Tegner Activity Score (TAS); a visual analog scale (VAS) for pain (0 – 100 mm or 0 – 10 cm scale).
  • Western Ontario and McMaster Universities Arthritis Index (WOMAC) which has three subscores: pain, which includes 5 items; stiffness, with 2 items; and physical function, with 17 items.
  • WOMAC response criteria is an improvement of 20% in at least 2 items together with an improvement of 10 points in the overall scale.
  • Cartilage is evaluated with the Magnetic Resonance Observation of Cartilage Repair Tissue (MOCART, 0 – 100 points, where higher scores indicate better cartilage repair).
  • Follow-up over months to years is of interest for relevant outcomes.

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

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

A systematic review and meta-analysis by Borakati et al. (2017) included 15 comparative studies (N = 582) on the use of MSCs to treat OA or focal osteochondral lesions.3 The studies (13 published and 2 unpublished data) included 5 RCTs, 1 case-control, and 9 cohort studies. A majority of the studies were conducted in Asia, and the source of the MSCs varied (bone marrow, blood, amniotic fluid, adipose tissue). The largest trial had only 56 participants, giving low statistical power for the individual studies. The overall quality of the evidence was considered low, with 3 studies rated as "satisfactory" and the rest rated "poor" on the Jadad scale. Pain assessment results were noted for each of the controlled studies, resulting in a pooled standardized mean difference of -1.27 (95% confidence interval [CI], -1.95 to -0.58) in favor of the group treated with MSCs. Reviewers reported a Z-statistic effect size of 3.62, again in favor of the groups treated with MSCs (p < .001); although there was high heterogeneity across controlled studies (I2 = 92%). There was also suggestion of publication bias; the investigators found 79 trials on clinicaltrials.gov, of which only 3 were listed as ‘complete with results,’ many trials had been inactive for several years, and 9 had ‘unknown’ status.

A systematic review and meta-analysis by Maheshwer et al. (2020) identified 25 studies with 439 participants that used MSCs for treatment of OA.4 Although 13 studies were considered level I RCTs by the authors (range of 7 to 40 participants), low quality RCTs would normally be downgraded to level II. Meta-analysis suggested improvement in self-reported function, but only in patients who underwent concomitant surgery, and there was no significant improvement in pain. Few studies reported on cartilage quality. Most of the studies were rated as poor or fair quality. Conclusions are limited due to substantial variability in MSC source, preparation, and concentration in the current literature.

Wiggers et al. (2021) conducted a systematic review of RCTs evaluating autologous mesenchymal stem cell therapy on patient-reported outcome measures and disease severity.5 Fourteen RCTs were identified in searches conducted through December 2020. Meta-analysis was precluded because most of the original trial data were not available for pooling and due to heterogeneity across studies. A total of 408 patients with knee osteoarthritis received MSC therapy derived from bone marrow, adipose tissue, or activated peripheral blood. After 1 year, 19 of 26 (73%) clinical outcome measures improved with MSCs compared with control. In the MSC group, patients improved by 1.8 to 4.4 points on the Visual Analogue Scale (0 to 10) and 18 to 32 points on the Knee Osteoarthritis Outcome Score (0 to 100). Four studies showed better disease severity on imaging after MSC compared with control at 1 year. Although the reviewers found a positive effect of autologous MSC therapy compared with control treatments, the certainty of the evidence was rated low to very low due to high risk of bias in the included studies (e.g., 10 of 14 RCTs were at high risk of bias on all outcomes) and high heterogeneity in the source, method of preparation, and dosage of injected stem cells in included RCTs.

A more focused systematic review and meta-analysis of 6 RCTs (N = 203) that evaluated cultured MSCs for OA was reported by Kim et al. (2020).6 Four of the studies used bone marrow-derived MSCs, 1 used adipose-derived cells, and the other cultured placental cells. Only 2 of the 6 studies were rated as low risk of bias. Pain outcomes measured with VAS and WOMAC pain scales were improved at 6 to 12 months, but there was no significant improvement in measures of WOMAC function or cartilage measured by magnetic resonance imaging.

Jin et al. (2022) also conducted a more focused systematic review and meta-analysis of 6 RCTs (N = 452) that evaluated intra-articular MSC injection in patients undergoing high tibial osteotomy (HTO).7 Results demonstrated that there were no significant differences in the International Knee Documentation Committee (IKDC) score and KOOS Pain and Symptoms subscales in patients who underwent HTO with or without the MSC injection. However, patients who received MSC injection had significantly greater improvements in Lysholm scores (mean difference, 2.55; 95% CI, 0.70 to 4.40; p = .007), and greater proportions of International Cartilage Regeneration and Joint Preservation Society (ICRS) grade 1 (p = .03) and grade 2 (p = .02) cartilage repair in the medial femoral condyle and grade 2 cartilage repair in the tibial plateau (p = .04).

The source of MSCs may have an impact on outcomes, but this is not well-understood, and the available literature uses multiple sources of MSCs. Because of the uncertainty over whether these products are equivalent, the evidence is grouped by the source of MSC.

Mesenchymal Stem Cells Expanded from Bone Marrow
Autologous Bone Marrow

Wakitani et al. (2002) first reported on the use of expanded MSCs for repair of cartilage defects.8 Cells from bone marrow aspirate of 12 patients with OA knees were culture-expanded, embedded in collagen gel, transplanted into the articular cartilage defect, and covered with autologous periosteum at the time of HTO. Clinical improvement did not differ between the experimental group and a group of 12 control patients who underwent HTO alone. Wakitani et al. (2007) have since published several cases of patients treated for isolated cartilage defects, with clinical improvement reported at up to 27 months.9 However, most of the defects appear to have been filled with fibrocartilage. A report from Wakitani et al. (2011) was a follow-up safety study of 31 of the 41 patients (3 patients had died, 5 had undergone total knee arthroplasty) who had received MSCs for articular cartilage repair in their clinics between 1998 and 2008.10 At a mean of 75 months (range, 5 – 137 months) since the index procedure, no tumors or infections were identified. Functional outcomes were not reported.

A publication from Centeno et al. (2010) of Regenerative Sciences in the United States described the use of percutaneously injected culture-expanded MSCs obtained from the iliac spine in 226 patients.11 Following harvesting, cells were cultured with autologous platelet lysate and reinjected under fluoroscopic guidance into peripheral joints (n = 213) or intervertebral discs (n = 13). Culture-expanded MSCs requires approval by the U.S. Food and Drug Administration (FDA) and is no longer offered in the United States.

The largest study included in the systematic review by Borakati et al. (2017) was by Wong et al. (2013), who reported on an RCT of cultured MSCs in 56 patients with OA who underwent medial opening wedge HTO and microfracture of a cartilage lesion (See Tables 2 and 3).12 Patients received an intra-articular injection of MSCs suspended in HA, or for controls, intra-articular injection of HA alone. The primary outcome was the IKDC score at 6 months, 1 year, and 2 years. Secondary outcomes were the TAS and LKS scores through 2 years and the MOCART scoring system by magnetic resonance imaging (MRI) at 1 year. All patients completed the 2-year follow-up. After adjusting for age, baseline scores, and time of evaluation, the group treated with MSCs showed significantly better scores on the IKDC (mean difference, 7.65 on 0 – 100 scale; p = .001), LKS (mean difference, 7.61 on 0 – 100 scale; p = .02), and TAS (mean difference, 0.64 on a 0-10 scale; p = .02) scores. The clinical significance of these differences is uncertain. Blinded analysis of MRI results found higher MOCART scores in the MSC group. The group treated with MSCs had a higher proportion of patients who had complete cartilage coverage of their lesions (32% vs. 0%), greater than 50% cartilage cover (36% vs. 14%), and complete integration of the regenerated cartilage (61% vs. 14%).

Emadedin et al. (2018) reported a triple-blind, placebo-controlled, phase 1/2 trial of expanded MSCs in 47 patients with OA of the knee.13 Compared to the placebo group, the MSC group showed statistically significant improvements in WOMAC pain and function subscales but not VAS. The WOMAC stiffness subscale improved to a similar extent in the 2 groups. Minimum Clinically Important Improvement and Patient Acceptable Symptom State were not significantly different between the 2 groups. Study limitations included the short duration of follow-up, statistical analysis, and lack of information regarding use of analgesic medications (see Tables 4 and 5).

Another phase 1/2 RCT of expanded MSCs was reported by Lamo-Espinosa et al. (2016, 2018) in 30 patients with OA of the knee.14,15 Two doses of MSCs (10 x 106, 100 x 106) were administered with HA and compared to injection of HA alone. VAS scores were significantly decreased in both MSC groups compared to baseline throughout the 12 months of follow-up, while the decrease in VAS in the control group was not statistically significant. Similarly, total WOMAC scores were statistically decreased only in the high dose group at 12 months. Four-year follow-up was available for 27 of the 30 participants. Two patients in the control group and 1 patient in the low dose group had undergone total knee arthroplasty. VAS scores were higher than at baseline in the HA control group but remained low in the 2 MSC groups. WOMAC scores at the long-term follow-up showed a similar course (see Table 3). Limitations of this study are described in Tables 4 and 5.

Table 2. Summary of Key RCT Characteristics

Study; Trial Countries Sites Dates Participants Interventions
          Active Comparator
Wong et al. (2013)12 Asia 1 NR Patients with OA who underwent HTO and microfracture (N = 56) Microfracture followed by expanded MSCs suspended in HA Microfracture plus HA alone
Emadedin et al. (2018)13 Iran 1 2012 – 2016 Patients who met the ACR clinical and radiological criteria for knee OA (N = 47) 40x106 expanded MSCs with serum albumin (n = 22) Placebo (n = 25)
Lamo-Espinosa et al. (2016, 2018)14,15 Spain 2 2012 – 2014 Patients who met the ACR clinical and radiological criteria for knee OA (N = 30) One of 2 doses of expanded MSCs with HA 10 x 106, 100 x 106 HA alone

ACR: American College of Rheumatology; HA: hyaluronic acid; HTO: high tibial osteotomy; MSC: mesenchymal stem cell; NR: not reported; OA: osteoarthritis; RCT: randomized controlled trial.

Table 3. Summary of Key RCT Results

Study

 

 

 

 

 

Wong et al. (2013)12 IKDC at 6 mo IKDC at 2 yr Tegner Activity Scale at 2 yr Lysolm Knee Score at 2 yr MOCART
N 56 56 56 56 56
Diff (95% CI) 7.65 (3.04 to 12.26)   0.64 (0.10 to 1.19) 7.61 (1.44 to 13.79) 19.6 (10.5 to 28.6)
p-Value .001   .021 .016 < .001

Emadedin et al. (2018)13

WOMAC Total

WOMAC Pain

WOMAC Stiffness

WOMAC Function

VAS

N 43 43 43 43 43
MSC (95% CI) -25.7 (-35.4 to 16) -35 (-44.9 to 25) -16.9 (-30.4 to 3.5) -22.9 (-32.9 to 12.9) -20.8 (-34.5 to 7.1)
Placebo (95% CI) 5.5 (-2.8 to 13.8) -12.2 (-18.5 to 5.9) -13.1 (-20.7 to 5.4) -9.5 (-21.8 to 2.7) -15.7 (-33.9 to 2.4)
Diff (95% CI) -13.5 (-24.3 to 2.7) -21.8 (-33.8 to 9.9) -7.4 (-25.4 to 10.5) -11.3 (-22.1 to 0.4) -5 (-28.1 to 18)
p-Value .01 .001 .40 .04 .65
Effect size (95% CI) 0.7 (0.1 to 1.4) 1.1 (0.4 to 1.7)   0.6 (0.03 to 1.2)  
Lamo-Espinosa et al. (2016, 2018)14,15 WOMAC Total at 12 mo, median (IQR) WOMAC Total at 4 yr, median (IQR) VAS at 4 yr, median (IQR)    
MSC low dose 21.5 (15, 26) 17 (13, 25.5) 2 (2, 5)    
MSC high dose 16.5 (12, 19) 16.5 (8, 23) 3 (3, 4)    
Control 13.5 (8, 33) 27 (17, 30) 7 (6, 7)  

CI: confidence interval; IKDC: International Knee Documentation Committee score; IQR: interquartile range; MOCART; Magnetic Resonance Observation of Cartilage Repair Tissue; MSC: mesenchymal stem cell; RCT: randomized controlled trial; VAS: visual analog scale; WOMAC: Western Ontario and McMaster Universities Arthritis Index.

Table 4. Study Relevance Limitations

Study Populationa Interventionb Comparatorc Outcomesd Follow-Upe
Wong et al. (2013)12 4. The population was restricted to patients younger than 55 4. The intervention included microfracture with/without stem cells      
Emadedin et al. (2018)13     2. Did not use an active control and use of analgesics was not reported 1. Evaluation of cartilage was not performed. 1, 2. Follow-up was reported out to 6 mo.
Lamo-Espinosa et al. (2016, 2018)14,15       1. Evaluation of cartilage was not performed.

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

Table 5. Study Design and Conduct Limitations

Study Allocationa Blindingb Selective Reportingc Data Completenessd Powere Statisticalf
Wong et al. (2013)12 3. Patients selected from 1 of 2 identical envelopes 1, 2, 3. Not blinded except for evaluation of magnetic resonance imaging        
Emadedin et al. (2018)13       . 3. Details of power analysis were not reported 1. The authors used non-inferiority compared to placebo and chi-square tests for continuous variables
Lamo-Espinosa et al. (2016, 2018)14,15   1, 2, 3. Not blinded     3. Details of power analysis were not reported 1. The authors used non-parametric tests for within-group comparisons rather than tests for repeated measures

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

Mesenchymal Stem Cells from Allogeneic Bone Marrow
Vega et al. (2015) reported on a small phase 1/2 RCT of 30 patients with OA unresponsive to conventional treatments.16 The MSC-treated group received an intra-articular injection of expanded allogeneic bone marrow MSCs from healthy donors, and the control group received an intra-articular injection of HA. Follow-up using standard outcome measures was performed at 3, 6, and 12 months post-injection. In the MSC-treated group, pain scores (VAS and WOMAC) decreased significantly between baseline and the 12-month follow-up, whereas pain scores in the control group did not improve significantly. A significant improvement in cartilage quality in the MSC group was supported by T2 MRI. Not reported was whether the patients or assessors were blinded to treatment.

Mesenchymal Stem Cells from Bone Marrow Aspirate Concentrate
Shapiro et al. (2017) reported on the results of a prospective, single-blind, placebo-controlled trial assessing 25 patients with bilateral knee pain from bilateral OA.17 Patients were randomized to BMAC into 1 knee and to saline placebo into the other. Fifty-two milliliters of bone marrow was aspirated from the iliac crests and concentrated in an automated centrifuge. The resulting BMAC was combined with platelet-poor plasma for injection into the arthritic knee and was compared with a saline injection into the contralateral knee, thereby using each patient as his or her control. Safety outcomes, pain relief, and function as measured by Osteoarthritis Research Society International measures and a VAS score were tracked initially at 1 week, 3 months, and 6 months post-procedure. Study patients experienced a similar relief of pain in both BMAC- and saline-treated arthritic knees.

Adipose-Derived Mesenchymal Stem Cells
Adipose-derived stem cells are multipotent MSCs that can be harvested from multiple anatomic locations and with greater ease than bone marrow-derived MSCs. The literature on adipose-derived MSCs for articular cartilage repair comes primarily from research groups in Korea. One group appears to have been providing this treatment as an option for patients for a number of years. They compared outcomes of this new add-on treatment with those for patients who only received other cartilage repair procedures.

Koh et al. (2014) reported on results of an RCT that evaluated cartilage healing after HTO in 52 patients with OA.18 Patients were randomized via sealed envelopes to HTO with the application of platelet-rich plasma (PRP) or to HTO with the application of PRP plus MSCs. A total of 44 patients completed second-look arthroscopy and 1- and 2-year clinical follow-ups. The primary outcomes were the KOOS (0 – 100 scale), the LKS score (0 – 100 scale), and a VAS for pain (0 – 100 scale). There were statistically significant differences between PRP only and PRP plus MSC on 2 of 5 KOOS subscales: pain (74 vs. 81.2, p < .001) and symptoms (75.4 vs. 82.8, p = .006), all respectively. There were also statistically significant differences on the final pain score between the PRP only (16.2) and PRP plus MSC groups (10.2; p < .001), but the final LKS score did not differ significantly between the PRP only (80.6) and PRP plus MSC groups (84.7; p = .36). Articular cartilage healing was rated as improved with MSCs following video review of second-look arthroscopy; blinding of this measure is unclear. There were limitations in study design (small sample size, short duration of follow-up). Also, significant improvements were found only on some outcomes, all significant differences in outcomes were modest in magnitude and, as a result, there is uncertainty about the clinical significance of the findings.

More recently, Zaffagnini et al. (2022) reported on results of an RCT that evaluated a single intra-articular injection of microfragmented adipose tissue or PRP in patients (N = 118) with knee OA.19 The primary outcomes were the IKDC subjective score and the KOOS pain subscore at 6 months. Overall, both treatments provided significant improvements from baseline in clinical outcomes, with no significant differences found between treatment groups. The IKDC scores significantly improved from baseline to 6 months, from 41.1 ± 16.3 to 57.3 ± 18.8 with microfragmented adipose tissue, and from 44.8 ± 17.3 to 58.4 ± 18.1 with PRP. The improvement in the KOOS pain subscore from baseline to 6 months was 58.4 ± 15.9 to 75.8 ± 17.4 with microfragmented adipose tissue and 63.5 ± 17.8 to 75.5 ± 16.1 with PRP. As a secondary outcome, more patients in the microfragmented adipose tissue group with moderate/severe knee OA reached the minimal clinically important difference for the IKDC score at 6 months compared with the PRP group (75.0% vs 34.6%, respectively; p = .005).

Mesenchymal Stem Cells from Peripheral Blood
A 2013 report from Asia has described a small RCT assessing the use of autologous peripheral blood MSCs for focal articular cartilage lesions. Fifty patients with grade 3 or 4 lesions of the knee joint underwent arthroscopic subchondral drilling followed by 5 weekly injections of HA. Half the patients were randomized to injections of peripheral blood stem cells or no further treatment. The peripheral blood stem cells were harvested after stimulation with recombinant human granulocyte colony-stimulating factor, divided in vials, and cryopreserved. At 6 months after surgery, HA and MSCs were re-administered over 3 weekly injections. At 18 months post-surgery, second-look arthroscopy on 16 patients in each group showed significantly higher histologic scores (» 10%) for the MSC group (1066 vs. 957 by independent observers) while blinded evaluation of MRI scans showed a higher morphologic score (9.9 vs. 8.5). There was no difference in IKDC scores between the 2 groups at 24 months after surgery.

Mesenchymal Stem Cells from Umbilical Cord Blood
Lim et al. (2021) reported on a RCT of 114 patients with large, full-thickness cartilage defects (International Cartilage Repair Society grade 4) treated with either a composite of umbilical cord-derived MSCs plus 4% hyaluronate (MSC-HA) or microfracture.20 The study consisted of a 48-week phase 3 clinical trial and a 5-year follow-up study. Of 114 patients randomized, 89 completed the phase 3 trial (78.1%), and 73 were enrolled in the follow-up study (64.0%). The primary outcome, proportion of participants with cartilage restoration equivalent to at least 1 grade improvement on the ICRS Macroscopic Cartilage Repair Assessment at 48-week arthroscopic evaluation, was 97.7% (42/43) in the MSC-HA group and 71.7% (33/46) in the microfracture group (odds ratio, 16.55; 95% CI, 2.06 to 133.03; p = .001). Both groups had significantly improved patient-reported pain scores (VAS pain, WOMAC, and IKDC scores) at 48 weeks versus baseline, but there was no significant difference between the 2 groups at this time point. From 36 to 60 months after intervention, the significant improvements from baseline were maintained in the MSC-HA group, whereas the improvements in VAS pain and WOMAC deteriorated in the microfracture group. This study had several limitations. There was no intervention group that received MSC alone, the comparator (microfracture) is not considered the standard of care for large, full-thickness cartilage defects, surgeons and participants were not blinded to treatment outcome, and there was high loss to follow-up. These limitations, along with a lack of improvement in patient-reported outcomes in the intervention group at 48 weeks, preclude drawing conclusions about the effectiveness of umbilical cord blood-derived MSCs in this population; higher-quality evidence from RCTs is needed.

Section Summary: Cartilage Defects
The evidence on MSCs for cartilage repair is increasing, although nearly all studies to date have been performed outside of the United States with a variety of methods of MSC preparation. Overall, the quality of evidence is low and there is a possibility of publication bias. The strongest evidence base is on MSCs expanded from bone marrow, which includes several phase 1/2 RCTs. Compared to either placebo or an active HA control, treatment with expanded MSCs has been shown to provide some improvement in pain and function. Limitations in these initial trials preclude reaching conclusions, but the results to date do support future study in phase 3 trials. Alternative methods of obtaining MSCs that have been reported in RCTs include peripheral blood, adipose tissue, and bone marrow concentrate. These have been reported in a smaller number of trials and with mixed results. Additional study in a larger sample of patients with longer follow-up would be needed to evaluate the long-term efficacy and safety of these procedures. FDA approval for these methods has also not been obtained.

Meniscal Defects
Clinical Context and Therapy Purpose

The purpose of stem cell therapy is to provide a treatment option that is an alternative to or an improvement on existing therapies in patients with meniscal defects.

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

Populations
The relevant population of interest is individuals with meniscal defects.

Interventions
The therapy being considered is stem cell therapy.

Comparators
Comparators of interest include conservative management.

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

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.
  • 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
Damage to the meniscal cartilage in the knee is a very common orthopedic injury and predisposes to the development of OA. The tissue is relatively avascular and does not spontaneously heal well.

Whitehouse et al. (2017) published a report on techniques of in vitro expansion of autologous-derived MSCs and a case series of the first-in-human implantation to treat meniscal defects in 5 patients.21 The regulatory framework in the United Kingdom allows cell manipulation and requires immunohistochemical documentation of the presence and volume of mesenchymal cells. Over the first 12 months postprocedure, 3 of the 5 patients were reported to have clinical symptom relief, which persisted through 24 months. MRI scans showing lack of meniscal displacement were the only other postoperative assessment. The 2 patients who failed to obtain symptom relief at 6 and 12 months had to repeat arthroscopic procedures with meniscectomy.

Vangsness et al. (2014) reported on an industry-sponsored phase 1/2 randomized, double-blind, multicenter Study of Chondrogen — Adult Universal Cell Delivered by Intra-Articular Injection Following Meniscectomy in Patients 18 – 60 Years (NCT00225095, NCT00702741) of cultured allogeneic MSCs (Chondrogen; Osiris Therapeutics) injected into the knee after partial meniscectomy.22 The 55 patients in this United States study were randomized to intra-articular injection of either 50´106 allogeneic MSCs, 150´106 allogeneic MSCs in HA, or an HA vehicle control at 7 to 10 days after meniscectomy. The cultured MSCs were derived from BMAC of unrelated donors. At 2-year follow-up, 3 patients in the low-dose MSC group had significantly increased meniscal volume measured by MRI (with an a priori determined threshold of at least 15%) compared with none in the control group or the high-dose MSC group. There was no significant difference between the groups in LKS scores. On subgroup analysis, patients with OA who received MSCs had a significantly greater reduction in pain at 2 years than patients who received HA alone. This trial appears to have been a post hoc analysis and, hence, should be considered preliminary. No serious adverse events were reported as related to the investigational treatment.

Section Summary: Meniscal Defects
The evidence on the use of MSCs to repair or regenerate damaged meniscal tissue consists of preclinical animal studies, first-in-human uncontrolled implantation of expanded autologous MSCs into meniscal tears, and an early-phase randomized trial of cultured allogeneic MSCs injected into the site of partial meniscectomy. Results are preliminary.

Joint Fusion Procedures
Clinical Context and Therapy Purpose

The purpose of stem cell therapy is to provide a treatment option that is an alternative to or an improvement on existing therapies in patients with joint fusion procedures.

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

Populations
The relevant population of interest is individuals with joint fusion procedures.

Interventions
The therapy being considered is stem cell therapy.

Comparators
Comparators of interest include iliac crest bone graft.

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

Follow-up over months to years is of interest for relevant outcomes.

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

  • To assess efficacy outcomes, comparative controlled prospective trials were sought, with a preference for RCTs.
  • 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
There is limited evidence on the use of allografts with stem cells for bone fusion of the extremities or spine or the treatment of nonunion. The results of several industry-sponsored, early-phase trials are available.

A prospective, clinical, and radiographic 12-month outcomes study (2016) of patients undergoing single-level anterior cervical discectomy and fusion (ACDF) for symptomatic cervical degenerative disc disease using a novel viable allogeneic stem cell and cancellous bone matrix (Trinity Evolution) was reported using historical controls as the comparator.23 The ACDF procedure was performed using the polyetheretherketone interbody spacer and bone graft substitute (Trinity Evolution) in 31 patients at multiple clinical sites. At 6 and 12 months, the primary endpoint of radiographic fusion was evaluated as determined by an independent radiographic review and the fusion rate was 78.6% at 6 months and 93.5% at 12 months. Secondary endpoints included a function as assessed by Neck Disability Index scores, and neck and arm pain as assessed by individual VAS scores. Neck function and neck and arm pain were reported as significantly improved at both 6 and 12 months post-procedure. Reported adverse events included carpal tunnel syndrome, minor pain, numbness, permanent and/or unresolved pain, and swelling. Independent medical adjudication of the 26 adverse events occurring in 31 patients found that no adverse events were definitely or probably related to Trinity Evolution. However, 5 adverse events were found to be possibly related to Trinity Evolution with 3 events of mild severity and 2 of moderate severity.

A similar study (2017) involving several of the same investigators and clinical sites reported on the clinical and radiographic evaluation of an allogeneic bone matrix containing stem cells (Trinity Evolution Viable Cellular Bone Matrix) in patients undergoing 2-level ACDF.24 This study involved 40 patients exposed to the ACDF and bone graft substitute procedure at 2 adjacent disc levels. A panel blinded to clinical outcomes reviewed 12-month dynamic motion plain radiographs and thin-cut computed tomography with multiplanar reconstruction. At 12 months, the per-subject and per-level fusion rates were 89.4% and 93.4%, respectively. The clinical function assessments using the Neck Disability Index and VAS scores were reported to have improved from baseline.

A 2015 prospective, multicenter, open-label clinical trial using a cryopreserved, donor mesenchymal cell scaffold (Trinity Evolution) was performed in subjects undergoing foot and/or ankle arthrodesis with surgeons’ preferred technique.25 A total of 103 subjects were prospectively enrolled at 10 participating sites. No restrictions were placed on the diagnosis, which included arthritis (primary OAs, posttraumatic OA, and rheumatoid), deformity, neuropathy (Charcot and diabetic), revision surgery, and degenerative joint disease, and arthrodesis was performed in 171 joints. The per-protocol population consisted of 92 patients at 6 months and 76 patients at 12 months, with 153 and 129 total arthrodeses, respectively. The primary endpoint was fusion at 6 months, as assessed from computed tomography scans and standard radiographs by an independent radiology consultant. At 6 months, the fusion rate for all patients was 68.5% and 81.1% for all joints. American Orthopaedic Foot and Ankle Society Hindfoot Scale scores for disability improved over time.

Eastlack et al. (2014) reported on outcomes from a series of 182 patients treated with ACDF using Osteocel Plus in a polyetheretherketone cage and anterior plating.26 At 24 months, 74% of patients (180/249 levels treated) were available for follow-up. These patients had significant improvements in clinical outcomes, with 87% of levels achieved solid bridging, and 92% of levels had a range of motion less than 3°. With 26% loss to follow-up at 24 months and lack of a standard of care control group, interpretation of these results is limited.

Section Summary: Joint Fusion Procedures
The evidence on the use of MSCs as a component of joint fusion procedures primarily comes from industry-sponsored, prospective, open-label procedures. Outcomes included radiologic assessments of fusion, sometimes made independently, and patient-reported measures (e.g., VAS scores). The MSCs used were cryopreserved allogeneic in origin. Presumptive benefits of allogeneic MSCs are that patients undergoing an orthopedic intervention procedure do not need another graft harvesting procedure and that dose of stem cells can be managed.

Osteonecrosis
Clinical Context and Therapy Purpose

The purpose of stem cell therapy is to provide a treatment option that is an alternative to or an improvement on existing therapies in patients with osteonecrosis.

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

Populations
The relevant population of interest is individuals with osteonecrosis.

Interventions
The therapy being considered is therapy with MSCs.

Comparators
Comparators of interest include core decompression.

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

Follow-up over months to years is of interest for relevant outcomes.

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

  • To assess efficacy outcomes, comparative controlled prospective trials were sought, with a preference for RCTs.
  • 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
At least 2 RCTs from Asia have evaluated the use of MSCs for osteonecrosis of the femoral head.

Mesenchymal Stem Cells Concentrated from Bone Marrow Aspirate Concentrate
Sen et al. (2012) randomized 40 patients (51 hips) with early-stage femoral head osteonecrosis to core decompression plus concentrated bone marrow MSCs or core decompression alone.27 Blinding of assessments in this small trial was not described. Harris Hip Score was significantly improved in the core decompression plus MSC group compared with the core decompression alone group at 12 months (scores, 83.65 vs. 76.68, p < .016) but not at 24 months (scores, 82.42 vs. 77.39; p = .09), all respectively. Kaplan-Meier analysis showed improved hip survival in the MSC group (mean, 51.9 weeks) compared with the core decompression group (mean, 46.7 weeks). There were no significant differences between groups in radiographic assessment or MRI results.

Mesenchymal Stem Cells Expanded From Bone Marrow
Zhao et al. (2012) reported on a randomized trial that included 100 patients (104 hips) with early-stage femoral head osteonecrosis treated with core decompression and expanded bone marrow MSCs or with core decompression alone.28 At 60 months post-surgery, 2 (3.7%) of the 53 hips treated with MSCs progressed and underwent vascularized bone grafting compared with 10 (23%) of 44 hips in the decompression group who progressed and underwent either vascularized bone grafting (n = 5) or total hip replacement (n = 5). The MSC group also had improved Harris Hip Scores compared with the control group on independent evaluation (data presented graphically). Lesion volume was also reduced by treatment with MSCs.

Section Summary: Osteonecrosis
Two small RCTs have compared core decompression alone with core decompression plus MSCs in patients with osteonecrosis of the femoral head. Both reported improvement in the Harris Hip Score in patients treated with MSCs, although it was not reported whether the patients or investigators were blinded to the treatment group. Hip survival was significantly improved following treatment with either expanded or concentrated MSCs. The effect appears to be larger with expanded MSCs than with concentrated MSCs. Additional, well-designed RCTs with a large number of patients are needed to permit greater certainty on the efficacy of this treatment for osteonecrosis.

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

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
A 2020 guideline from American Association of Orthopaedic Surgeons on the management of glenohumeral joint OA, endorsed by several other societies, states that injectable biologics such as stem cells cannot be recommended in the treatment glenohumeral joint OA.29 There was consensus from the panel that better standardization and high-quality evidence from clinical trials is needed to provide definitive evidence on the efficacy of biologics in glenohumeral OA. The strength of evidence was rated as no reliable scientific evidence to determine benefits and harms.

The 2021 guideline on treatment of osteoarthritis of the knee does not address stem cell injections.30

American Association of Neurological Surgeons
In 2014, the American Association of Neurological Surgeons guidelines on fusion procedures for degenerative disease of the lumbar spine relevant to this evidence review have indicated that “The use of demineralized bone matrix (DBM) as a bone graft extender is an option for 1- and 2-level instrumented posterolateral fusions. Demineralized Bone Matrix: Grade C (poor level of evidence).”31

American College of Rheumatology and Arthritis Foundation
In 2019, guidelines from the American College of Rheumatology and Arthritis Foundation on osteoarthritis (OA) of the hand, hip, and knee gave a strong recommendation against stem cell injections in patients with knee and/or hip OA, noting the heterogeneity in preparations and lack of standardization of techniques.32, No recommendation was made for hand OA, since efficacy of stem cells has not been evaluated.

U.S. Preventive Services Task Force Recommendations
Not applicable

Ongoing and Unpublished Clinical Trials
Some currently unpublished trials that might influence this review are listed in Table 6.

Table 6. Summary of Key Trials

NCT No. Trial Name Planned Enrollment Completion Date
Ongoing      
NCT02582489 Prospective, Randomized, Double-blind Clinical Trial to Investigate the Efficacy of Autologous Bone Marrow Aspirate Concentrate Post-Meniscectomy 100 Dec 2022
NCT03067870 Transplantation of Autologous Purified Bone Marrow Derived Specific Populations of Stem Cells and Mesenchymal Stem Cells in Patients With Rheumatoid Arthritis 100 Feb 2022
NCT04368806a A 48-Weeks, Phase 2b/3a, Double-Blind, Randomized, Placebo Controlled, Multi-center, Superiority Study to Evaluate the Efficacy and Safety of JointStem, Autologous Adipose Tissue Derived Mesenchymal Stem Cells in Patients Diagnosed as Knee Osteoarthritis 140 Dec 2023
NCT02838069 A Phase IIb, Prospective, Multicentre, Double-blind, Triple-arm, Randomized Versus Placebo Trial, to Assess the Efficacy of a Single Injection of Either 2 or 10 x 106 Autologous Adipose Derived Mesenchymal Stromal Cells (ASC) in the Treatment of Mild to Moderate Osteoarthritis (OA) of the Knee, Active and Unresponsive to Conservative Therapy for at Least 12 Months 153 Mar 2024
NCT04448106a Clinical Study for Subjects With Osteoarthritis of Knees, Hips, and Shoulders Using a Combination of Intravenous Infusions With Intra-articular Injection of Autologous Adipose Tissue-Derived Mesenchymal Stem Cells (AdMSCs) 300 Aug 2025
NCT04427930 Long-Term Safety and Efficacy Extension Study Of Autologous Adipose-Derived MesenchymalStem Cells (JOINTSTEM) in Patients With Knee Osteoarthritis: A Phase III Extension Study 260 Dec 2027
NCT05288725 A Study to Evaluate the Safety, and Efficacy of Minimally Manipulated Autologous Bone Marrow Aspirate to Treat Knee Osteoarthritis in Patients 120 Dec 2024
NCT05517434 Intra-Articular Autologous Bone Marrow Aspirate Concentrate vs Placebo Injection and Lipoaspirate Concentrate With Leukocyte-Poor Platelet Rich Plasma vs Placebo Injection Evaluations for Treatment of Knee OsteoArthritis: The ABLE OA Double-Blinded Randomized Clinical Trial 148 Dec 2024
Unpublished      
NCT04310215a A Multi-center, Single-blind, Randomized, Phase III Clinical Trial to Evaluate the Efficacy and Safety of Adding CARTISTEM® on Microfracture in Patients With Talar Chondral or Osteochondral Defect 102 Nov 2022
NCT03818737 Randomized Multicenter Phase 3 Single-blind Trial Comparing the Efficacy of Corticosteroid Control to Mesenchymal Stem Cell Preparations From Autologous Bone Marrow Concentrate (BMAC), Adipose-derived Stem Cells in the Form of Stromal Vascular Fraction (SVF), and Third-party Human Mesenchymal Stem Cells Manufactured From Umbilical Cord Tissue for the Treatment of Unilateral Knee Osteoarthritis (OA) 480 Jul 2022
NCT04043819a Evaluation of Safety and Exploratory Efficacy of PSC-01, an Autologous Adipose-derived Stromal Vascular Fraction Cell Therapy Product for the Treatment of Knee Osteoarthritis 125 Jan 2021
NCT03990805a Multi-center, Randomized, Double-Blind, Placebo Controlled Phase 3 Clinical Trial to Evaluate Efficacy and Safety of Mesenchymal Stem Cells JointStem in Patients With Knee Osteoarthritis 260 Dec 2020


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

References 

  1. Goldberg A, Mitchell K, Soans J, et al. The use of mesenchymal stem cells for cartilage repair and regeneration: a systematic review. J Orthop Surg Res. Mar 09 2017; 12(1): 39. PMID 28279182
  2. U.S. Food & Drug Administration. Regulatory Considerations for Human Cells, Tissues, and Cellular and Tissue-Based Products: Minimal Manipulation and Homologous Use. https://www.fda.gov/regulatory-information/search-fda-guidance-documents/regulatory-considerations-human-cells-tissues-and-cellular-and-tissue-based-products-minimal
  3. Borakati A, Mafi R, Mafi P, et al. A Systematic Review And Meta-Analysis of Clinical Trials of Mesenchymal Stem Cell Therapy for Cartilage Repair. Curr Stem Cell Res Ther. Feb 23 2018; 13(3): 215-225. PMID 28914207
  4. Maheshwer B, Polce EM, Paul K, et al. Regenerative Potential of Mesenchymal Stem Cells for the Treatment of Knee Osteoarthritis and Chondral Defects: A Systematic Review and Meta-analysis. Arthroscopy. Jan 2021; 37(1): 362-378. PMID 32497658
  5. Wiggers TG, Winters M, Van den Boom NA, et al. Autologous stem cell therapy in knee osteoarthritis: a systematic review of randomised controlled trials. Br J Sports Med. Oct 2021; 55(20): 1161-1169. PMID 34039582
  6. Kim SH, Djaja YP, Park YB, et al. Intra-articular Injection of Culture-Expanded Mesenchymal Stem Cells Without Adjuvant Surgery in Knee Osteoarthritis: A Systematic Review and Meta-analysis. Am J Sports Med. Sep 2020; 48(11): 2839-2849. PMID 31874044
  7. Jin L, Yang G, Men X, et al. Intra-articular Injection of Mesenchymal Stem Cells After High Tibial Osteotomy: A Systematic Review and Meta-analysis. Orthop J Sports Med. Nov 2022; 10(11): 23259671221133784. PMID 36452339
  8. Wakitani S, Imoto K, Yamamoto T, et al. Human autologous culture expanded bone marrow mesenchymal cell transplantation for repair of cartilage defects in osteoarthritic knees. Osteoarthritis Cartilage. Mar 2002; 10(3): 199-206. PMID 11869080
  9. Wakitani S, Nawata M, Tensho K, et al. Repair of articular cartilage defects in the patello-femoral joint with autologous bone marrow mesenchymal cell transplantation: three case reports involving nine defects in five knees. J Tissue Eng Regen Med. 2007; 1(1): 74-9. PMID 18038395
  10. Wakitani S, Okabe T, Horibe S, et al. Safety of autologous bone marrow-derived mesenchymal stem cell transplantation for cartilage repair in 41 patients with 45 joints followed for up to 11 years and 5 months. J Tissue Eng Regen Med. Feb 2011; 5(2): 146-50. PMID 20603892
  11. Centeno CJ, Schultz JR, Cheever M, et al. Safety and complications reporting on the re-implantation of culture-expanded mesenchymal stem cells using autologous platelet lysate technique. Curr Stem Cell Res Ther. Mar 2010; 5(1): 81-93. PMID 19951252
  12. Wong KL, Lee KB, Tai BC, et al. Injectable cultured bone marrow-derived mesenchymal stem cells in varus knees with cartilage defects undergoing high tibial osteotomy: a prospective, randomized controlled clinical trial with 2 years' follow-up. Arthroscopy. Dec 2013; 29(12): 2020-8. PMID 24286801
  13. Emadedin M, Labibzadeh N, Liastani MG, et al. Intra-articular implantation of autologous bone marrow-derived mesenchymal stromal cells to treat knee osteoarthritis: a randomized, triple-blind, placebo-controlled phase 1/2 clinical trial. Cytotherapy. Oct 2018; 20(10): 1238-1246. PMID 30318332
  14. Lamo-Espinosa JM, Mora G, Blanco JF, et al. Intra-articular injection of two different doses of autologous bone marrow mesenchymal stem cells versus hyaluronic acid in the treatment of knee osteoarthritis: long-term follow up of a multicenter randomized controlled clinical trial (phase I/II). J Transl Med. Jul 31 2018; 16(1): 213. PMID 30064455
  15. Lamo-Espinosa JM, Mora G, Blanco JF, et al. Intra-articular injection of two different doses of autologous bone marrow mesenchymal stem cells versus hyaluronic acid in the treatment of knee osteoarthritis: multicenter randomized controlled clinical trial (phase I/II). J Transl Med. Aug 26 2016; 14(1): 246. PMID 27565858
  16. Vega A, Martín-Ferrero MA, Del Canto F, et al. Treatment of Knee Osteoarthritis With Allogeneic Bone Marrow Mesenchymal Stem Cells: A Randomized Controlled Trial. Transplantation. Aug 2015; 99(8): 1681-90. PMID 25822648
  17. Shapiro SA, Kazmerchak SE, Heckman MG, et al. A Prospective, Single-Blind, Placebo-Controlled Trial of Bone Marrow Aspirate Concentrate for Knee Osteoarthritis. Am J Sports Med. Jan 2017; 45(1): 82-90. PMID 27566242
  18. Koh YG, Kwon OR, Kim YS, et al. Comparative outcomes of open-wedge high tibial osteotomy with platelet-rich plasma alone or in combination with mesenchymal stem cell treatment: a prospective study. Arthroscopy. Nov 2014; 30(11): 1453-60. PMID 25108907
  19. Zaffagnini S, Andriolo L, Boffa A, et al. Microfragmented Adipose Tissue Versus Platelet-Rich Plasma for the Treatment of Knee Osteoarthritis: A Prospective Randomized Controlled Trial at 2-Year Follow-up. Am J Sports Med. Sep 2022; 50(11): 2881-2892. PMID 35984721
  20. Lim HC, Park YB, Ha CW, et al. Allogeneic Umbilical Cord Blood-Derived Mesenchymal Stem Cell Implantation Versus Microfracture for Large, Full-Thickness Cartilage Defects in Older Patients: A Multicenter Randomized Clinical Trial and Extended 5-Year Clinical Follow-up. Orthop J Sports Med. Jan 2021; 9(1): 2325967120973052. PMID 33490296
  21. Whitehouse MR, Howells NR, Parry MC, et al. Repair of Torn Avascular Meniscal Cartilage Using Undifferentiated Autologous Mesenchymal Stem Cells: From In Vitro Optimization to a First-in-Human Study. Stem Cells Transl Med. Apr 2017; 6(4): 1237-1248. PMID 28186682
  22. Vangsness CT, Farr J, Boyd J, et al. Adult human mesenchymal stem cells delivered via intra-articular injection to the knee following partial medial meniscectomy: a randomized, double-blind, controlled study. J Bone Joint Surg Am. Jan 15 2014; 96(2): 90-8. PMID 24430407
  23. Vanichkachorn J, Peppers T, Bullard D, et al. A prospective clinical and radiographic 12-month outcome study of patients undergoing single-level anterior cervical discectomy and fusion for symptomatic cervical degenerative disc disease utilizing a novel viable allogeneic, cancellous, bone matrix (trinity evolution™) with a comparison to historical controls. Eur Spine J. Jul 2016; 25(7): 2233-8. PMID 26849141
  24. Peppers TA, Bullard DE, Vanichkachorn JS, et al. Prospective clinical and radiographic evaluation of an allogeneic bone matrix containing stem cells (Trinity Evolution® Viable Cellular Bone Matrix) in patients undergoing two-level anterior cervical discectomy and fusion. J Orthop Surg Res. Apr 26 2017; 12(1): 67. PMID 28446192
  25. Jones CP, Loveland J, Atkinson BL, et al. Prospective, Multicenter Evaluation of Allogeneic Bone Matrix Containing Viable Osteogenic Cells in Foot and/or Ankle Arthrodesis. Foot Ankle Int. Oct 2015; 36(10): 1129-37. PMID 25976919
  26. Eastlack RK, Garfin SR, Brown CR, et al. Osteocel Plus cellular allograft in anterior cervical discectomy and fusion: evaluation of clinical and radiographic outcomes from a prospective multicenter study. Spine (Phila Pa 1976). Oct 15 2014; 39(22): E1331-7. PMID 25188591
  27. Sen RK, Tripathy SK, Aggarwal S, et al. Early results of core decompression and autologous bone marrow mononuclear cells instillation in femoral head osteonecrosis: a randomized control study. J Arthroplasty. May 2012; 27(5): 679-86. PMID 22000577
  28. Zhao D, Cui D, Wang B, et al. Treatment of early stage osteonecrosis of the femoral head with autologous implantation of bone marrow-derived and cultured mesenchymal stem cells. Bone. Jan 2012; 50(1): 325-30. PMID 22094904
  29. American Academy of Orthopaedic Surgeons. Management of Glenohumeral Joint Osteoarthritis Evidence-Based Clinical Practice Guideline. https://www.aaos.org/globalassets/quality-and-practice-resources/glenohumeral/gjo-cpg.pdf. Updated March 23, 2020. 
  30. American Academy of Orthopaedic Surgeons. Management of Osteoarthritis of the Knee (Non-Arthroplasty). https://www.aaos.org/globalassets/quality-and-practice-resources/osteoarthritis-of-the-knee/oak3cpg.pdf. Updated August 31, 2021. 
  31. Kaiser MG, Groff MW, Watters WC, et al. Guideline update for the performance of fusion procedures for degenerative disease of the lumbar spine. Part 16: bone graft extenders and substitutes as an adjunct for lumbar fusion. J Neurosurg Spine. Jul 2014; 21(1): 106-32. PMID 24980593
  32. Kolasinski SL, Neogi T, Hochberg MC, et al. 2019 American College of Rheumatology/Arthritis Foundation Guideline for the Management of Osteoarthritis of the Hand, Hip, and Knee. Arthritis Care Res (Hoboken). Feb 2020; 72(2): 149-162. PMID 31908149

Coding Section

Codes Number Description
CPT    
  38206  Blood-derived hematopoietic progenitor cell harvesting for transplantation, per collection; autologous
  38230  Bone marrow harvesting for transplantation 
  38241  Hematopoietic progenitor cell (HPC); autologous transplantation 
  0630T (effective 01/01/2021) Percutaneous injection of allogeneic cellular and/or tissue-based product, intervertebral disc, unilateral or bilateral injection, with CT guidance, lumbar; each additional level (List separately in addition to code for primary procedure)
  20930 Allograft, morselized, or placement of osteopromotive material, for spine surgery only (List separately in addition to code for primary procedure). NOTE: This is a generic graft add on injection code to spine surgery which could be used for stem cells injection..
  20931 Allograft, structural, for spine surgery only (List separately in addition to code for primary procedure)
  20939 Bone marrow aspiration for bone grafting, spine surgery only, through separate skin or fascial incision (List separately in addition to code for primary procedure)
  20999 Unlisted procedure, musculoskeletal system, general (Use for aspiration of bone marrow for the purpose of bone grafting, other than spine surgery and other therapeutic musculoskeletal applications)
  0263T Intramuscular autologous bone marrow cell therapy, with preparation of harvested cells, multiple injections, one leg, including ultrasound guidance, if performed; complete procedure including unilateral or bilateral bone marrow harvest
  0264T Intramuscular autologous bone marrow cell therapy, with preparation of harvested cells, multiple injections, one leg, including ultrasound guidance, if performed; complete procedure excluding bone marrow harvest
  0265T Intramuscular autologous bone marrow cell therapy, with preparation of harvested cells, multiple injections, one leg, including ultrasound guidance, if performed; unilateral or bilateral bone marrow harvest only for intramuscular autologous bone marrow cell therapy
  0489T Autologous adipose-derived regenerative cell therapy for scleroderma in the hands; adipose tissue harvesting, isolation and preparation of harvested cells including incubation with cell dissociation enzymes, removal of non-viable cells and debris, determination of concentration and dilution of regenerative cells
  0490T Autologous adipose-derived regenerative cell therapy for scleroderma in the hands; multiple injections in one or both hands
  0565T Autologous cellular implant derived from adipose tissue for the treatment of osteoarthritis of the knees; tissue harvesting and cellular implant creation
  0566T ; injection of cellular implant into knee joint including ultrasound guidance, unilateral
HCPCS C9359 Porous purified collagen matrix bone void filler (Integra Mozaik Osteoconductive Scaffold Putty, Integra Os Osteoconductive Scaffold Putty), per 0.5 cc
  C9362 Porous purified collagen matrix bone void filler (Integra Mozaik Osteoconductive Scaffold Strip), per 0.5 cc
ICD-10-CM M00.00- M25.9 Arthropathies code range
  M84.30-M84.9 Disorder of continuity of bone code range
  M91.0-M94.9 Chondropathies code range
  S32.000A-S32.9xxS Fracture of lumbar spine and pelvis code range
  S42.001A-S42.92xS Fracture of shoulder and upper arm code range
  S52.001A-S52.92xS Fracture of forearm code range
  S62.001A-S62.92xS Fracture at wrist and hand level code range
  S72.001A-S72.92xS Fracture of femur code range
  S82.001A-S82.92xS Fracture of lower leg, including ankle code range
  S92.001A-S92.919S Fracture of foot and toe, except ankle code range
ICD-10-PCS   ICD-10-PCS codes are only used for inpatient services. There is no specific ICD-10-PCS code for this procedure. The following codes might be used.
  3E0U3GC Administration, physiological systems and anatomical regions, introduction, percutaneous, joints, other therapeutic substance
  3E0V3GC Administration, physiological systems and anatomical regions, introduction, percutaneous, bones, other therapeutic substance
  3E0U0GB Administration, physiological systems and anatomical regions, introduction, open, joints, other therapeutic substance, bone morphogenetic protein (no other options under open approach)
  3E0V0GB Administration, physiological systems and anatomical regions, introduction, open, bones, other therapeutic substance, bone morphogenetic protein (no other options under open approach)
  6A550ZV, 6A551ZV Hematopoietic stem cell pheresis, code by single or multiple
  07DQ0ZZ, 07DQ3ZZ,07DR0ZZ, 07DR3ZZ,07DS0ZZ, 07DS3ZZ Bone marrow extraction, code by body part (sternum, iliac or vertebral) and approach (open or percutaneous)
Type of Service Surgery  
Place of Service Outpatient/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. 

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

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

History From 2024 Forward     

01012024  NEW POLICY

04/17/2024 Annual review, no change to policy intent. Updating guidelines to specify that this policy is not intended to address unprocessed allograft bone or products that do not require mixing with stem cells. 

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