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Autologous Cell-derived Tissue Engineered Cartilage for Repairing Articular Cartilage Lesions

Primary Purpose

Cartilage Diseases

Status
Unknown status
Phase
Not Applicable
Locations
Study Type
Interventional
Intervention
biomimetic cartilage matrix + autologous chondrocytes
arthroscopic debridement
microfracture surgery
Sponsored by
Chinese PLA General Hospital
About
Eligibility
Locations
Arms
Outcomes
Full info

About this trial

This is an interventional treatment trial for Cartilage Diseases

Eligibility Criteria

14 Years - 50 Years (Child, Adult)All SexesDoes not accept healthy volunteers

Inclusion Criteria:

  • Patients with full-thickness cartilage injury in knee and ankle joints
  • Patients with normal joint movement and stable joint (without injury or less than 1/3 excision of the meniscus; normal cruciate ligament, lateral and medial collateral accessory ligament, or normal Q angle and patellofemoral joint trajectory after transplantation, or corrected to normal by surgery), without valgus or varus deformity
  • Patients 14-50 years of age.
  • Patients with focal cartilage defects diagnosed by arthroscopy, Outerbridge III/IV grade, cartilage defect size 2.5-10 cm2, intact articular surface (lower than grade II injury according to Outerbridge classification), one or two lesions in the same joint.
  • Patients and their families are informed of the treatment and provide signed informed consent.

Exclusion Criteria:

  • Poor health
  • Blood diseases
  • Topical steroid therapy within three months
  • Bleeding tendency
  • Drug addiction (including narcotic, anesthetic or alcohol addiction)
  • Inflammatory joint disease (specific or non-specific arthritis)
  • Contagious viral infection
  • Metabolic diseases (gout or rheumatism)
  • Body mass index > 30 kg/m2
  • Pregnant or lactating women, or planning to become pregnant within 1 year after initial registration
  • Psychological mental illness, cannot cope with rehabilitation

Sites / Locations

    Arms of the Study

    Arm 1

    Arm 2

    Arm Type

    Experimental

    Experimental

    Arm Label

    the experimental group

    the control group

    Arm Description

    Patients in the experimental group will be treated with the biomimetic cartilage matrix combined with autologous chondrocytes. The entire course of treatment includes two surgeries. The first surgery will be performed to observe articular cartilage damage by arthroscopy and assess treatment potential. If the patient's condition meets the surgical requirement, we will extract cartilage from the fossa intercondylar non-weight-bearing area during the first surgery. Chondrocytes will be in vitro-amplified and inoculated into the cartilage scaffold. The fully prepared seeded scaffold will be implanted into the site of injury during the second surgery.

    Patients in the control group will be subjected to arthroscopic debridement and microfracture surgery.

    Outcomes

    Primary Outcome Measures

    Change of Magnetic resonance imaging(MRI)
    using joint MRI, cartilage thickness and fusion with surrounding normal cartilage and subchondral bone, as well as the presence or absence of articular effusion and subchondral bone edema will be assessed.

    Secondary Outcome Measures

    Change of Lysholm score
    The Lysholm score is out of a possible 100 points.
    Change of 2000 IKDC subjective knee evaluation score
    A higher score indicates better knee function. IKDC score is used to evaluate knee function and symptoms. 100 points represents no restrictions of daily life and sports.
    Change of KOOS survey
    Change of the VAS pain scale
    Joint pain will be evaluated with the VAS pain scale; 0 = painless, 10 = severe pain.

    Full Information

    First Posted
    May 11, 2016
    Last Updated
    May 11, 2016
    Sponsor
    Chinese PLA General Hospital
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    1. Study Identification

    Unique Protocol Identification Number
    NCT02770209
    Brief Title
    Autologous Cell-derived Tissue Engineered Cartilage for Repairing Articular Cartilage Lesions
    Official Title
    Autologous Cell-derived Tissue Engineered Cartilage for Repairing Articular Cartilage Lesions: a Protocol for a Prospective, Randomized, Controlled Clinical Trial
    Study Type
    Interventional

    2. Study Status

    Record Verification Date
    May 2016
    Overall Recruitment Status
    Unknown status
    Study Start Date
    February 2012 (undefined)
    Primary Completion Date
    August 2013 (Actual)
    Study Completion Date
    June 2016 (Anticipated)

    3. Sponsor/Collaborators

    Responsible Party, by Official Title
    Principal Investigator
    Name of the Sponsor
    Chinese PLA General Hospital

    4. Oversight

    Data Monitoring Committee
    Yes

    5. Study Description

    Brief Summary
    This study is aimed at evaluating the feasibility and effectiveness of a completely natural tissue engineered cartilage, composed of a self-made tissue engineered oriented scaffold and autologous chondrocytes, for repairing articular cartilage damage following injury. And it is also aimed at investigating the safety of tissue engineered cartilage transplantation.
    Detailed Description
    Injured articular cartilage has limited capacity for self repair. Without timely, early and effective treatment, damage to the articular cartilage progressively worsens, resulting in joint swelling, pain and dysfunction. The patient ultimately develops osteoarthritis and will be required to undergo artificial joint replacement. Clinical therapy for cartilage damage includes microfracture surgery and autologous osteochondral transplantation. However, the microfracture technique is limited to small-scale damage, and autologous osteochondral transplantation is hindered by limited supply. With advances in material science, cell biology, biomechanics and bioreactor technology, the new generation of biomimetic tissue engineered osteochondral composites display great potential for the repair of cartilage damage. Currently, in cartilage tissue engineering, seed cells are derived from autologous or allogeneic chondrocytes, mesenchymal stem cells, embryonic stem cells or pluripotent stem cells. Increasing evidence indicates that bone marrow mesenchymal stem cells can be induced to differentiate into chondrocytes, and these cells have been successfully used in the treatment of large-size bone defects, cartilage lesions and spinal cord injury. The quality and quantity of bone mesenchymal stem cells gradually decrease with age, especially in patients with degenerative diseases. Adipose stem cells and umbilical cord mesenchymal stem cells are abundant and have similar characteristics to bone mesenchymal stem cells, and both of these cell types can be induced to differentiate into chondrocytes. Adipose stem cells and umbilical cord mesenchymal stem cells have been used to repair cartilage defects, but the findings are still preliminary, and these cells cannot be harvested or cultured in large quantities. Furthermore, the use of embryonic stem cells is complicated by ethical considerations. As a consequence, autologous chondrocytes are optimal seed cells for cartilage tissue engineering. The transplantation of autologous chondrocytes in combination with tissue engineered cartilage scaffolds to repair cartilage damage requires researchers to focus on two major issues, namely, (i) the in vitro amplification of chondrocytes and (ii) the preparation of biocompatible chondrocyte scaffolds. The preparation of chondrocyte scaffolds requires advanced technique, and currently, only the Institute of Orthopedics at the Chinese PLA General Hospital has the capacity to produce acellular cartilage; there is no other source of tissue engineered cartilage scaffolds in China. A proprietary allogeneic acellular cartilage-oriented scaffold was successfully created by the Cartilage Tissue Engineering Research Group, Institute of Orthopedics, Chinese PLA General Hospital (with intellectual property rights). The innovative scaffold simulates the composition and spatial structural characteristics of normal cartilage. The preparation methods are as follows: articular cartilage is pulverized to obtain natural cartilage extracellular matrix, which is identical in biochemical composition to extracellular matrix of natural articular cartilage. Then, a porous sponge-like scaffold is prepared using the freeze-drying technique. In vitro experiments and large-animal articular cartilage injury repair experiments have produced good results. Using this material, our research group prepared biomimetic cartilage tissue engineered scaffolds, which mimic the structural characteristics of natural articular cartilage extracellular matrix. This allogeneic acellular cartilage scaffold has the following characteristics: (1) it is derived from allogeneic cartilage, and the extracellular matrix remains intact after allografting, helping to maintain the numerous components of normal cartilage, particularly type II collagen and proteoglycans, resulting in enhanced repair. Cartilage scaffolds used outside of China are mainly composed of types I and III collagen or hyaluronic acid, and vary greatly from natural cartilage components. The original cartilage structure is difficult to reproduce with these types of scaffolds, and fibrous cartilage may affect treatment outcome. (2) The biomimetic scaffold has a similar three-dimensional structure to that of normal articular cartilage, which is the oriented scaffold structure. The scaffold imitates the orientation of normal cartilage cells, which are arranged perpendicular to the surface, and provides a paratactic columnar structure that contributes to the columnar arrangement of cells. This structure in combination with type II collagen and proteoglycans derived from normal articular cartilage results in a scaffold structure that is extremely close to that of normal joint cartilage. Consequently, the repaired cartilage will have normal structure and function. (3) The oriented scaffold has a good biomechanical property. Its compressive stress is better than the non-oriented scaffold in wet and dry conditions. (4) The oriented scaffold has good biocompatibility. Preliminary experiments have investigated the immune responses of the oriented scaffold of heterogeneous (porcine) and conspecific (rabbit) acellular cartilage. After the oriented scaffold was implanted into the rabbit, its immune responses were observed from the aspects of cellular immunity and humoral immunity. Results suggested that its immunogenicity was low. Thus, it is verified that the oriented scaffold of acellular cartilage has good biocompatibility. Adverse Events Security Standard operating procedures for adverse events and severe adverse events will be developed to ensure that any adverse reactions during the experiment will be treated quickly to protect the participants. Definitions 2.1 Adverse events Adverse medical events may occur after cartilage transplantation or microfracture surgery, but they do not necessarily have a causal relationship with treatment. Common adverse reactions after cartilage transplantation include fever, joint pain, swelling and effusion. Common adverse reactions after microfracture surgery include fever, joint pain, joint swelling and effusion. 2.2 The severity of adverse events Adverse events will be classified into three levels: general adverse events, vital adverse events and severe adverse events. 2.3 Relationship with tissue engineered cartilage The correlation between adverse events and tissue-engineered cartilage will be categorized into "definitely related", "probably related", "possibly unrelated", "irrelevant" or "undetermined". 2.4 Severe adverse events All events occurring during the trial requiring hospitalization or prolonged hospitalization, or resulting in disability, or affecting the ability to work, or with a risk of death or life-threatening events will be recorded. Adverse event recording All adverse events during the experiment will be collected until the end of the study. Recording and reporting All adverse events will be recorded by physicians, including description of adverse events, occurrence time, end time, severity, frequency, and treatment record. Once a severe adverse event occurs, physicians will not only give necessary treatment, but also truthfully report to the local Food and Drug Administration Bureau and the National Food and Drug Administration Bureau within 24 hours, as well as promptly report to the Ethics Committee. The data, treatment and follow-up results will be noted in the report. Follow-up observation of non-severe and severe adverse events If a patient suffers a non-severe adverse event, the course and outcome will be closely monitored. The course of severe adverse events will be recorded in follow-up reports or summary reports. Patients will also be monitored, and observations will be recorded for a period of 30 days after a seizure. Statistical Analysis Study hypotheses All hypotheses will be evaluated with two-tailed tests. A value of P < 0.05 will be considered statistically significant. Baseline data comparability will be assessed. Two-tailed statistical analysis will be performed with α = 5%. Number of cases A total of 100 patients will be involved in this study and divided into two groups, with 50 cases in each group. Experimental analysis Experimental data will be analyzed using statistical software, SPSS 22.0. Measurement data will be expressed as the mean ± SD, median, maximum, minimum and quartiles; count data will be presented as a percentage (%). Count data between groups will be compared using chi-square test or Fisher exact test. Measurement data between groups will be compared using t-test. Nonparametric variables between groups will be compared using rank sum test. Statistical analysis Statistical analysis will be performed by professional statisticians who will not be involved in the study. All data will be input and reviewed, and a statistical analysis report will be prepared. Administration Preservation of articular cartilage Cartilage tissue will be preserved and transported in a 50 mL centrifuge tube containing 8 mL of tissue preservation solution, placed on a test tube rack on top of an ice pack, at 4 °C under sterile conditions. Cartilage tissue will be transferred to the Institute of Orthopedics at the Chinese PLA General Hospital within 12 hours. Chondrocyte culture and preservation Autologous chondrocytes will be cultured and amplified in strict accordance with the standards and requirements of the National Institutes for Food and Drug Control. All images and data will be recorded. Cartilage seed cells will be frozen in liquid nitrogen. Data quality assurance (1) Researchers will fill in a case report form (CRF) accurately. (2) Inspectors will regularly verify that all data recorded are correct and complete, and that they are consistent with original records, and will be quickly transferred to the data administrator. (3) The data administrator will further examine CRF tables and return the form to the researchers. (4) Two data clerks will input duplicate data into a computer database. (5) The two separate sets of data will be compared by computer software, and modified according to the CRF. (6) Quality control: 5% of all case data will be randomly selected for manual checking. If the data error is greater than 0.15%, all the data in the database will be manually checked.

    6. Conditions and Keywords

    Primary Disease or Condition Being Studied in the Trial, or the Focus of the Study
    Cartilage Diseases

    7. Study Design

    Primary Purpose
    Treatment
    Study Phase
    Not Applicable
    Interventional Study Model
    Parallel Assignment
    Masking
    ParticipantInvestigator
    Allocation
    Randomized
    Enrollment
    100 (Anticipated)

    8. Arms, Groups, and Interventions

    Arm Title
    the experimental group
    Arm Type
    Experimental
    Arm Description
    Patients in the experimental group will be treated with the biomimetic cartilage matrix combined with autologous chondrocytes. The entire course of treatment includes two surgeries. The first surgery will be performed to observe articular cartilage damage by arthroscopy and assess treatment potential. If the patient's condition meets the surgical requirement, we will extract cartilage from the fossa intercondylar non-weight-bearing area during the first surgery. Chondrocytes will be in vitro-amplified and inoculated into the cartilage scaffold. The fully prepared seeded scaffold will be implanted into the site of injury during the second surgery.
    Arm Title
    the control group
    Arm Type
    Experimental
    Arm Description
    Patients in the control group will be subjected to arthroscopic debridement and microfracture surgery.
    Intervention Type
    Biological
    Intervention Name(s)
    biomimetic cartilage matrix + autologous chondrocytes
    Intervention Type
    Procedure
    Intervention Name(s)
    arthroscopic debridement
    Intervention Type
    Procedure
    Intervention Name(s)
    microfracture surgery
    Primary Outcome Measure Information:
    Title
    Change of Magnetic resonance imaging(MRI)
    Description
    using joint MRI, cartilage thickness and fusion with surrounding normal cartilage and subchondral bone, as well as the presence or absence of articular effusion and subchondral bone edema will be assessed.
    Time Frame
    Before treatment and month 3, month 6, month 12, month 18 after surgery
    Secondary Outcome Measure Information:
    Title
    Change of Lysholm score
    Description
    The Lysholm score is out of a possible 100 points.
    Time Frame
    Before treatment and month 3, month 6, month 12, month 18 after surgery
    Title
    Change of 2000 IKDC subjective knee evaluation score
    Description
    A higher score indicates better knee function. IKDC score is used to evaluate knee function and symptoms. 100 points represents no restrictions of daily life and sports.
    Time Frame
    Before treatment and month 3, month 6, month 12,month 18 after surgery
    Title
    Change of KOOS survey
    Time Frame
    Before treatment and month 3, month 6, month 12,month 18 after surgery
    Title
    Change of the VAS pain scale
    Description
    Joint pain will be evaluated with the VAS pain scale; 0 = painless, 10 = severe pain.
    Time Frame
    Before treatment and month 3, month 6, month 12,month 18 after surgery

    10. Eligibility

    Sex
    All
    Minimum Age & Unit of Time
    14 Years
    Maximum Age & Unit of Time
    50 Years
    Accepts Healthy Volunteers
    No
    Eligibility Criteria
    Inclusion Criteria: Patients with full-thickness cartilage injury in knee and ankle joints Patients with normal joint movement and stable joint (without injury or less than 1/3 excision of the meniscus; normal cruciate ligament, lateral and medial collateral accessory ligament, or normal Q angle and patellofemoral joint trajectory after transplantation, or corrected to normal by surgery), without valgus or varus deformity Patients 14-50 years of age. Patients with focal cartilage defects diagnosed by arthroscopy, Outerbridge III/IV grade, cartilage defect size 2.5-10 cm2, intact articular surface (lower than grade II injury according to Outerbridge classification), one or two lesions in the same joint. Patients and their families are informed of the treatment and provide signed informed consent. Exclusion Criteria: Poor health Blood diseases Topical steroid therapy within three months Bleeding tendency Drug addiction (including narcotic, anesthetic or alcohol addiction) Inflammatory joint disease (specific or non-specific arthritis) Contagious viral infection Metabolic diseases (gout or rheumatism) Body mass index > 30 kg/m2 Pregnant or lactating women, or planning to become pregnant within 1 year after initial registration Psychological mental illness, cannot cope with rehabilitation
    Overall Study Officials:
    First Name & Middle Initial & Last Name & Degree
    Quanyi Guo, Ph.D
    Organizational Affiliation
    Institute of Orthopedics, Chinese PLA Hospital, Beijing, China
    Official's Role
    Principal Investigator

    12. IPD Sharing Statement

    Plan to Share IPD
    Undecided
    Citations:
    PubMed Identifier
    29110690
    Citation
    Ma N, Wang H, Xu X, Wan Y, Liu Y, Wang M, Yu W, Dai Y, Peng J, Guo Q, Yu C, Lu S. Autologous-cell-derived, tissue-engineered cartilage for repairing articular cartilage lesions in the knee: study protocol for a randomized controlled trial. Trials. 2017 Nov 6;18(1):519. doi: 10.1186/s13063-017-2251-6.
    Results Reference
    derived

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    Autologous Cell-derived Tissue Engineered Cartilage for Repairing Articular Cartilage Lesions

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