Ignite Creation Date:
2025-12-26 @ 2:40 PM
Ignite Modification Date:
2025-12-26 @ 2:40 PM
Study NCT ID:
NCT07044206
Status:
NOT_YET_RECRUITING
Last Update Posted:
2025-06-29
First Post:
2025-06-16
Is NOT Gene Therapy:
False
Has Adverse Events:
False
Brief Title:
Comparaison of Interbody Bone Fusion Between Two Osteoinductive Bioactive Bone Substitutes After Anterior Lumbar Interbody Arthrodesis in Degenerative Lumbar Disc Surgery in Adults
Sponsor:
University Hospital, Montpellier
Organization:
Study Overview
Official Title:
Prospective Randomized Comparative Study of Interbody Bone Fusion Between Two Osteoinductive Bioactive Bone Substitutes After Anterior Lumbar Interbody Arthrodesis in Degenerative Lumbar Disc Surgery in Adults
Status:
NOT_YET_RECRUITING
Status Verified Date:
2025-06
Last Known Status:
None
Delayed Posting:
No
If Stopped, Why?:
Not Stopped
Has Expanded Access:
False
If Expanded Access, NCT#:
N/A
Has Expanded Access, NCT# Status:
N/A
Acronym:
FUSALIF
Brief Summary:
Disc degeneration is a progressive deterioration process of the intervertebral disc, which can manifest as significant low back pain and a loss of mobility that interferes with daily activities. This condition is naturally age-related and exacerbated by traumatic events, lifestyle factors, and individual genetic susceptibilities. Treatment for advanced disc degeneration typically involves surgery (spinal fusion) aimed at addressing and fusing the affected intervertebral discs using an interbody implant combined with a bone graft.
Although the use of interbody implants promotes temporary fusion, long-term success largely depends on the bone substitute used, with failure rates ranging from 10 to 20% (unsuccessful fusion, persistent symptoms, need for reoperation). Historically, autologous bone grafting was the standard, but it carries disadvantages related to pain and invasiveness. Synthetic, bioactive bone substitutes are now used, although their effectiveness varies.
Animal studies support the hypothesis that a new substitute based on specific osteo-immunology technology (MagnetOs, Kuros) could offer superior results compared to autologous bone grafts and competing osteo-inductive materials, while being minimally invasive. This study aims to evaluate its properties in terms of bone fusion and its impact on functional scores in patients, hypothesizing a significant improvement in fusion rates and functional scores with this new substitute.
Although the use of interbody implants promotes temporary fusion, long-term success largely depends on the bone substitute used, with failure rates ranging from 10 to 20% (unsuccessful fusion, persistent symptoms, need for reoperation). Historically, autologous bone grafting was the standard, but it carries disadvantages related to pain and invasiveness. Synthetic, bioactive bone substitutes are now used, although their effectiveness varies.
Animal studies support the hypothesis that a new substitute based on specific osteo-immunology technology (MagnetOs, Kuros) could offer superior results compared to autologous bone grafts and competing osteo-inductive materials, while being minimally invasive. This study aims to evaluate its properties in terms of bone fusion and its impact on functional scores in patients, hypothesizing a significant improvement in fusion rates and functional scores with this new substitute.
Detailed Description:
Degenerative lumbar spine disease increasingly relies on surgery to treat and fuse one or more pathological intervertebral discs. The transabdominal retroperitoneal, or anterior, approach allows full access to and treatment of the diseased disc, enabling a more physiological restoration of spinal alignment. Implants placed in the interbody position provide immediate vertebral stabilization, while the bone graft or bone substitute added to the interbody implant enables long-term fusion through neo-ossification of the segment.
The quality and speed of fusion achieved largely depend on the bone substitute used, and this fusion is a key factor in obtaining good functional outcomes for the patient. In approximately 10 to 20% of cases, this fusion does not succeed, resulting in persistent pain symptoms and potentially requiring reoperation.
Historically, to achieve this fusion, autologous bone was harvested from another anatomical site, most often the iliac crest. This autologous bone graft requires an additional incision, which is often associated with pain and discomfort. For these reasons, synthetic or biologic bone substitutes have been developed by pharmaceutical engineering to avoid bone harvesting, and are now routinely used in clinical practice.
To date, many bioactive bone substitutes have obtained marketing authorization, but their effectiveness varies depending on their physicochemical composition. It is accepted that the fusion rate could improve by up to 60% depending on the bone substitute used.
Animal studies support the hypothesis that a new bone substitute, referred to here as Substitute A, based on specific osteoimmunology technology (MagnetOs, Kuros), is equivalent to the current gold standard (autologous bone graft) in terms of achieved fusion, and superior to competing osteoinductive products that are routinely used at Montpellier University Hospital and in most other hospitals to achieve spinal fusion (6). This suggests the possibility of achieving equivalent outcomes through a faster, less invasive, less painful procedure with no limitation on the volume of substitute used.
Due to its favorable characteristics, this product (Substitute A) was recently endorsed by the Commission for Medicines and Sterile Medical Devices (CMDMS) of Montpellier University Hospital, authorizing its appropriate use in this indication, though currently limited to a small number of batches. This project would allow us to demonstrate the benefits of Substitute A so that it could subsequently be adopted for routine use.
This trial is a single-center, prospective, randomized, controlled superiority trial, with single-blind evaluation of the primary outcome measure. This study aims to include 100 patients. A non-stratified randomization with random block sizes will be performed to allocate participants in a 1:1 ratio into the following groups: Group A receiving the investigational device (bone substitute, Magnetos Putty, Kuros Medical) and Group B receiving the routine treatment (bone substitute, GlassBone Putty, Noraker).
Simplified study calender:
Visit 1: Information between 6 months and 1 month before Day 0 Preoperative consultation to determine the indication for surgery and the date of the operation
* Presentation of the trial, description of the practical aspects of the study and randomization process
* Provision of the information sheet
Visit 1: Before the intervention (Day -1) Re-presentation of the trial, description of the practical aspects of the study and randomization process
* Verification of eligibility criteria
* Obtaining informed consent
* Collection of demographic data : age, sex, occupation, Body Mass Index (BMI), medication use, smoking, alcohol consumption, medical history)
* Health questionnaires : Visual Analogue Scale (VAS), Oswestry Disability Index (ODI)
* Collection of imaging data : high-resolution lumbar Computed Tomography (CT) scan and lumbar X-ray)
Visit 2: Day 0 (Surgical intervention day) Randomization will be performed at the earliest, the day before or on the day of the intervention.
Patients will be randomized into either the conventional or experimental arm. The allocated arm will be communicated to the neurosurgeon investigator responsible for the operation. The patient will remain blinded to their treatment group.
The surgical intervention will be performed according to the standard anterior lumbar fusion procedure, except for the bone substitute, which will vary according to randomization.
Visit 3: 3 months (+/- 15 days)
Following the usual care for patients who have undergone anterior lumbar interbody fusion:
* Low back and radicular pain (VAS)
* Functional score (ODI)
* Imaging for a 3-month assessment (high-resolution lumbar CT scan)
* Collection of additional data (return to work, medication use)
Visit 4: 12 months (+/- 15 days)
Following the usual care for patients who have undergone anterior lumbar interbody fusion:
* Low back and radicular pain (VAS)
* Functional score (ODI)
* High-resolution lumbar CT scan and lumbar X-ray in weight-bearing and dynamic positions
* Collection of additional data (return to work, medication use...)
The quality and speed of fusion achieved largely depend on the bone substitute used, and this fusion is a key factor in obtaining good functional outcomes for the patient. In approximately 10 to 20% of cases, this fusion does not succeed, resulting in persistent pain symptoms and potentially requiring reoperation.
Historically, to achieve this fusion, autologous bone was harvested from another anatomical site, most often the iliac crest. This autologous bone graft requires an additional incision, which is often associated with pain and discomfort. For these reasons, synthetic or biologic bone substitutes have been developed by pharmaceutical engineering to avoid bone harvesting, and are now routinely used in clinical practice.
To date, many bioactive bone substitutes have obtained marketing authorization, but their effectiveness varies depending on their physicochemical composition. It is accepted that the fusion rate could improve by up to 60% depending on the bone substitute used.
Animal studies support the hypothesis that a new bone substitute, referred to here as Substitute A, based on specific osteoimmunology technology (MagnetOs, Kuros), is equivalent to the current gold standard (autologous bone graft) in terms of achieved fusion, and superior to competing osteoinductive products that are routinely used at Montpellier University Hospital and in most other hospitals to achieve spinal fusion (6). This suggests the possibility of achieving equivalent outcomes through a faster, less invasive, less painful procedure with no limitation on the volume of substitute used.
Due to its favorable characteristics, this product (Substitute A) was recently endorsed by the Commission for Medicines and Sterile Medical Devices (CMDMS) of Montpellier University Hospital, authorizing its appropriate use in this indication, though currently limited to a small number of batches. This project would allow us to demonstrate the benefits of Substitute A so that it could subsequently be adopted for routine use.
This trial is a single-center, prospective, randomized, controlled superiority trial, with single-blind evaluation of the primary outcome measure. This study aims to include 100 patients. A non-stratified randomization with random block sizes will be performed to allocate participants in a 1:1 ratio into the following groups: Group A receiving the investigational device (bone substitute, Magnetos Putty, Kuros Medical) and Group B receiving the routine treatment (bone substitute, GlassBone Putty, Noraker).
Simplified study calender:
Visit 1: Information between 6 months and 1 month before Day 0 Preoperative consultation to determine the indication for surgery and the date of the operation
* Presentation of the trial, description of the practical aspects of the study and randomization process
* Provision of the information sheet
Visit 1: Before the intervention (Day -1) Re-presentation of the trial, description of the practical aspects of the study and randomization process
* Verification of eligibility criteria
* Obtaining informed consent
* Collection of demographic data : age, sex, occupation, Body Mass Index (BMI), medication use, smoking, alcohol consumption, medical history)
* Health questionnaires : Visual Analogue Scale (VAS), Oswestry Disability Index (ODI)
* Collection of imaging data : high-resolution lumbar Computed Tomography (CT) scan and lumbar X-ray)
Visit 2: Day 0 (Surgical intervention day) Randomization will be performed at the earliest, the day before or on the day of the intervention.
Patients will be randomized into either the conventional or experimental arm. The allocated arm will be communicated to the neurosurgeon investigator responsible for the operation. The patient will remain blinded to their treatment group.
The surgical intervention will be performed according to the standard anterior lumbar fusion procedure, except for the bone substitute, which will vary according to randomization.
Visit 3: 3 months (+/- 15 days)
Following the usual care for patients who have undergone anterior lumbar interbody fusion:
* Low back and radicular pain (VAS)
* Functional score (ODI)
* Imaging for a 3-month assessment (high-resolution lumbar CT scan)
* Collection of additional data (return to work, medication use)
Visit 4: 12 months (+/- 15 days)
Following the usual care for patients who have undergone anterior lumbar interbody fusion:
* Low back and radicular pain (VAS)
* Functional score (ODI)
* High-resolution lumbar CT scan and lumbar X-ray in weight-bearing and dynamic positions
* Collection of additional data (return to work, medication use...)
Study Oversight
Has Oversight DMC:
False
Is a FDA Regulated Drug?:
False
Is a FDA Regulated Device?:
False
Is an Unapproved Device?:
None
Is a PPSD?:
None
Is a US Export?:
False
Is an FDA AA801 Violation?: