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Schol, J. Regenerative Medicine Targeted for Intervertebral Disc Disease. Encyclopedia. Available online: https://encyclopedia.pub/entry/19445 (accessed on 16 November 2024).
Schol J. Regenerative Medicine Targeted for Intervertebral Disc Disease. Encyclopedia. Available at: https://encyclopedia.pub/entry/19445. Accessed November 16, 2024.
Schol, Jordy. "Regenerative Medicine Targeted for Intervertebral Disc Disease" Encyclopedia, https://encyclopedia.pub/entry/19445 (accessed November 16, 2024).
Schol, J. (2022, February 15). Regenerative Medicine Targeted for Intervertebral Disc Disease. In Encyclopedia. https://encyclopedia.pub/entry/19445
Schol, Jordy. "Regenerative Medicine Targeted for Intervertebral Disc Disease." Encyclopedia. Web. 15 February, 2022.
Regenerative Medicine Targeted for Intervertebral Disc Disease
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This entry is adapted from the peer-reviewed paper 10.3390/medicina58020267

Low back pain is critical health, social, and economic issue in modern societies. This disease is often associated with intervertebral disc degeneration; however, contemporary treatments are unable to target this underlying pathology to alleviate the pain symptoms. Cell therapy offers a promising novel therapeutic that, in theory, should be able to reduce low back pain through mitigating the degenerative disc environment. 

cell therapy stem cells intervertebral disc degeneration spine low back pain regeneration clinical trials minimally invasive surgery

1. Introduction

Low back pain (LBP) and neck pain currently form the primary causes of global disability [1], and prevalence is likely to increase with a generally aging population, further imposing concerns on the socioeconomic affordability of healthcare and social security expenses [2][3]. Both disorders are generally associated with the intervertebral discs (IVD) being subdued to progressive age- and non-age-related degeneration [4]. IVD constitute the fibrocartilage tissues between each two vertebrae, capable of distributing complex loads along the spine. The IVD is composed of a highly hydrophilic core, the nucleus pulposus (NP), which is laterally enclosed by multiple collagenous lamellae, cumulatively termed the annulus fibrosus (AF) (Figure 1A). The IVD is connected to each vertebra with a thin hyaline cartilage layer, the endplate, which forms the primary source of nutrient, waste, and gas exchange for the predominantly avascular discs [5]. The IVD derives its function through a careful interplay of the high osmotic pressure engendered by the proteoglycan-rich NP, which is constricted by a stiff AF, jointly enabling the IVD to absorb relatively large forces while retaining flexibility. Tissue-specific cells are responsible for maintaining and remodeling the region-distinct extracellular matrix (ECM) to maintain the IVD and its biomechanical features. Although the etiology and progression of IVD degeneration remain somewhat obscure, it is generally associated with a progressive decline in cell numbers and a cellular switch toward a more catabolic and senescent state [6][7] (Figure 1B). Consequently, deteriorating the quality and organization of the ECM, thereby compromising the discs biomechanical limits [8]. Jointly, these changes engender an inflammatory environment, promoting immunogenic cell migration and potentially inducing blood vessel and neuronal ingrowth into the disc, thereby conceivably sensitizing the discs or inflaming regional spinal nerves [5][9]. Moreover, the progressive decline of the biomechanical sturdiness of the disc may allow AF tissue to bulge or burst, compressing neuronal and vascular tissues along the spine. Alternatively, the loss of water retention in the NP leads to a decline in disc height and mechanical features that further stress other spinal tissues, e.g., facet joints and tendons, to thereby be involved in the pathogenesis.
Figure 1. Illustration depicting (A) a healthy IVD with hydrated nucleus pulposus (NP) and organized annulus fibrosus (AF), (B) subsequent degenerative cascade resulting in AF disorganization loss of NP hydration, endplate vascularization, and disc height, and (C) Injection of de novo cells into the NP and their three proposed potential therapeutic mechanisms; i.e., (i) attraction of regenerative cells or limiting catabolic/inflammatory cells into the IVD, (ii) reactive and directing local cells to produce extracellular matrix (ECM), and (iii) integration into the IVD and contribution to ECM production directly.
Contemporary treatment strategies remain primarily palliative (Figure 2). Early-stage LBP is commonly treated with physiotherapy or the administration of analgesics [10]. Consequently, LBP has been indicated as the primary reason for non-cancer opioid prescription [11]. Nevertheless, high-quality evidence supporting the efficacy of these conservative therapies is severely lacking [10]. At later stages of LBP, surgical intervention may be employed. Generally, this involves either excision of protruding disc material in cases of disc herniation or complete removal of discs followed by arthroplasty or arthrodesis. Although these procedures are commonplace and rates are dramatically increasing [12][13], their efficacy remains largely controversial [14][15]. In addition, none of these interventions aim to resolve the degenerative cascade underlying the pathology, and furthermore, can trigger degenerative cascades in neighboring discs [16]. For treatment investigations, a slight reduction in the number of LBP patients, associated medical care, or back pain intensity can make a significant impact on socioeconomic costs, and translate to a large cohort of patients. These new strategies being explored focus on limiting, halting, and even reversing disc degeneration in an attempt to revitalize the disc’s composition and thus its biomechanical features, thereby resolving or preventing associated spinal disorders [17][18]. These include regenerative approaches, e.g., growth factor injection [19], gene therapy [20], tissue engineering [21][22], and biomaterial-applications [23], each being at different stages of development and presenting different levels of success in preclinical and/or clinical studies. Moreover, each strategy will likely be most effective at different stages of the degeneration cascade (Figure 2). One particular regenerative approach that has gained significant momentum in the recent decade is cell therapy [24][25]. Cell therapy involves the transplantation of additional cell populations into the IVD with the aim to either (i) directly impact IVD repair by repopulating the disc with de novo active cells to reestablish appropriate ECM production or (ii) indirectly induce IVD repair by stimulating or attracting regional cells to induce a more anabolic state, by for example tempering inflammation or to promote (re)initiation of IVD-ECM production by native cells (Figure 1C). The optimal strategy for restoring degenerative IVD in a clinic setting remains to be determined and is likely highly dependent on the degenerative state and disease indications. Multiple cell products and transplantation strategies have now been assessed in the clinical, showing promising results. Nevertheless, due to the accelerating speed of publication on this topic [24], new advancements in cellular therapy and new insights on potential limitations require continuous and careful review of progress in the field. 
Medicina 58 00267 g002 550
Figure 2. Illustrative plot depicting the contemporary treatment gap for low back pain associated with disc degeneration, in which only treatment options are available (oval) in either the mild or severe disc degeneration and low back pain range. New proposed techniques (blocks) likely will be most effective at different stages of degeneration and are likely less invasive than the surgical intervention currently employed.

2. Cell Therapy

Cell therapy is a therapeutic strategy in which generally living cells are introduced into the patient to replace or repair damaged tissue or otherwise alter endemic cell behavior. The most well-established form of cell therapy remains bone marrow transplantation for leukemia patients; however, since its first descriptions in 1968 [26][27], a wide range of other cell therapies have been postulated and examined, including regenerative strategies, cancer treatment, immunomodulation, or otherwise [28]. For the IVD, cellular therapeutics are commonly designed specifically for regenerative purposes, in which the transplanted or infused cells are expected to produce or stimulate the production of appropriate IVD-ECM or otherwise reduce the inflammatory and catabolic environment that typifies a degenerating IVD. As such, the cell product needs to either have the capacity to (1) survive and excel within the degenerating IVD to directly contribute to matrix product, (2) generate strong (paracrine)signaling able to promote an anabolic switch in native cells, or (3) support the recruitment of regenerative cells or otherwise limit the migration of fibrotic/catabolic cells into the IVD. Multiple in vivo animal studies have suggested the ability of transplanted cells to limit and sometimes even reverse the degeneration process [29][30][31]. Cell transplantation into the IVD is commonly employed through minimally invasive surgery, involving a percutaneous injection commonly through a 21- or 22-gauge needle [24] under fluoroscopic guidance into the IVD space, but can also involve systemic infusion or local transplantation. Intradiscally injected cells can potentially be maintained in the IVD space due to the enclosed nature of the disc or, otherwise, might be retained by encapsulation in a hydrogel, tissue graft, or other carriers [32]. Otherwise, cells transplanted outside the IVD could either migrate into the IVD to induce their regenerative effect or otherwise effectuate a more anabolic environment through paracrine signaling [33]. Multiple cell types have been examined as the agent engendering the repair, and these will be discussed in further detail below.

3. Mesenchymal Stromal Cells

Mesenchymal stromal cells (MSC), often falsely termed mesenchymal stem cells, usually involve a heterogeneous population of multipotent and more committed progenitor cells with relatively high proliferation capacity [34]. These cells can be sourced from multiple tissues; both are most often derived from bone marrow, adipose tissue, peripheral blood, or umbilical cords. Notably, however, the different MSC sources have been linked to differences in potency and differentiation inclinations [35][36][37]. MSC are of particular interest due to their easy accessibility and expandability [25]. Unlike other cell types, MSC can with relative ease be aspirated from healthy and young donors as well as from autologous sources [24]. Moreover, the MSC are characterized by their ability to differentiate toward a chondrogenic cell type, including the induction of a high rate of proteoglycan production [38][39][40]. Additionally, MSC possess an innate immunomodulatory capacity and could potentially limit the inflammatory environment of the IVD upon transplantation [41]. Nevertheless, their survival and capacity to strive in the IVD remain an aspect requiring careful examination [42][43]. For example, MSC subjected to IVD environmental factors have been shown to severely reduce proliferation and chondrogenic potency [44]. Although MSC have been shown capable of surviving and differentiating in the IVD of a range of animal models, their full NP cell phenotypical characteristics have not yet been reported [37]. Moreover, due to the unmatured nature of the MSC following transplantation and potential migration or leakage out of the IVD, they could potentially give rise to undesired differentiation and tissue formation, e.g., osteophyte as observed by Vadala et al. [45]. Finally, MSC have also been shown potent inducers of angiogenesis, particularly sourced from adipogenic tissue, which could further aggravate the degenerative cascade [46][47]. These practical benefits and opportunities should be carefully weighed out to the potential risks.
For human clinical trials, MSC are by far the most common cell type being examined. At current, MSC products are either sourced from adipose [48][49], bone marrow [50][51][52][53][54][55][56][57][58], or umbilical cord [59] tissues (Table 1) and applied either as an autologous or allogenic cell product. Two reports on adipose-derived MSC (AD-MSC) trials, involving a combined 18 patients, suggested that intradiscal injection at a 1-year follow-up was able to show a trend of [48] or significant [49] improvement in both visual analog pain scores (VAS) as well as Oswestry disability index (ODI). Interestingly, Piccirilli et al. [48] and Kumar et al. [49] reported an improvement in MRI signal intensity in 80% of examined discs and 30% of patients, respectively, suggesting to some extent the ability of the MSC to support IVD regeneration in some cases.
Table 1. Overview of reported clinical trials, case series, and case reports on cell transplantation for IVD repair.
  Trial Design Outcomes
  Sponsor,
Study [Ref]		 Trial Type Control Product
(Type)		 Dose (Cell/mL) Cohort (n) FU
(y)		 Pain Disability MRI SAE
Mesenchymal Stromal Cells Piccirilli [48] Case series None AD-MSC
(Autologous)		 ns/~1 mL 8 1 Trend of VAS improvement Trend of ODI improvement 80% of disc regained signal intensity None
Kumar
[49]		 PhaseI/IIa trial None AD-MSC
(Autologous)		 20 × 106/
2 mL HA		 5 1 Significantly enhanced VAS Significantly enhanced ODI and SF-36 3/10 patients presented enhanced intensity None
40 × 106/
2 mL HA		 5
Henriksson [50] Prospective study None BM-MSC
(Autologous)		 1 × 106/ns 10 <3 - - - Calcium deposits observed in 1/4 patients
Wang
[51]		 Prospective study None BM-MSC
(Allogenic)		 4 × 1 × 106 (/kg BW)/10 mL * 31 <1 - - Ankylosing spondylitis features mitigated None
Elabd
[57]		 Unspecified None BM-MSC
(Autologous)		 31 (±14) × 106/0.25–1 mL PL 5 6 - Trend of improvement in strength and mobility - None
Yoshikawa [52] Case series None BM-MSC
(Autologous)		 ns/ns 2 2 Trend of VAS improvement Trend of amended JOA scores Trend increased signal intensity None
Citospin/TerCel,
Noriega [53][54]		 RCT, blinded, phase I/II Paravertebral muscle anesthesia BM-MSC
(Allogenic)		 25 × 106/
2 mL		 12 1 Significant VAS improvement, significantly higher than control Significant ODI improvement, significantly higher than control Significantly enhanced Pfirrmann grading while worsening in control None
ITRT,
Orozco [55]		 Phase I/II trial None BM-MSC
(Autologous)		 10 (±5) × 106/ns 10 1 Significant VAS improvement Significant ODI and SF-36 improvements Significant increase in signal intensity None
Regenexx,
Centeno [56][57]		 Prospective study None BM-MSC + PL
(Autologous)		 1–3 × 106/10–20% PL 1–2 mL, +3–5 mL PL (epidural) 33 7 Significant NPS improvement Trend of FRI score improvement 85% showed reduction in disc bulge size None
Mesoblast,
Amirdelfan [58]		 RCT, blinded, phase II (1) Saline
injection
(2) HA injection		 BM-MSC
(Allogenic)		 6 × 106/2 mL HA 30 2 Significant VAS improvement, significantly higher than sham control Significant ODI improvement, significantly higher than sham control No clear difference in Pfirrmann grades 8/60 SAE compared to 4/40 in control, 1 case of discitis
18 × 106/2 mL HA 30
Pang [59] Case series None UC-MSC
(Allogenic)		 10 × 106/1 mL 2 2 Trend of VAS improvement Trend of ODI improvement 1/2 patients showed increase in signal intensity None
Chondrogenic cells NOVOCART®,
Tschugg [60][61]		 RCT, blinded phase I/II PEG-HA injection IVD cells
(Autologous)		 ns/0.5–2 mL PEG-HA 12 <1 - - No improvements reported None
Meisel [62][63] RCT Sequestrectomy only IVD cells + Sequestrectomy
(Autologous)		 ns/ns 22 >5 Trend of VAS improvement compared to control Trend of ODI improvement compared to control Significant improvement signal intensity compared to control None
Mochida [64] Case series None IVD cells
(Autologous)		 1 × 106/0.7 mL 9 3 Trend of LBP subscale improvement Trend of JOA improvement Signal intensity maintained. 1/9 showed Pfirrmann-grade improvement None
NuQu®,
Coric
[65]		 Phase I trial None AC
(Allogenic)		 10–20 × 106/1–2 mL
Fibrin		 15 1 Significant NRS improvement Significant ODI and SF-36 improvements 10/13 patients presented MRI ameliorations None
Vivex Biomedical,
Beall
[66][67][68]		 RCT, crossover study (1) placebo, (2) conservative care “Spine-derived” cells in NP tissue allograft
(Allogenic)		 >6 × 106/1.25–1.75 mL NP allograft 140 (+37) ** 1 Significant VAS improvement, not different from placebo group Significant ODI improvement, not different from placebo group, unless stratified for younger patients (<42 y) - 11 SAE in allograft and 1 in crossover cohort, 6 considered treatment related; including osteomyelitis and bacteremia
Other/Combined Bioheart,
Comella [69]		 Prospective study None SVF + PRP (Autologous) 30–60 × 106/1–3 mL PRP 15 1 Trend of VAS and pain rating improvements Minimal improvements in disability and QoL scores - None
Pettine [70][71] Prospective study None BMC
(Autologous)		 1–2 × 242–363 × 106/2–3 mL 26 3 Significant VAS improvements Significant ODI improvements 40% present Pfirrmann-grade improvement None
Subach
[72]		 Case report None BMA + Adipose tissue + Plasma
(Autologous)		 ns/3 mL 1 1 - - - Disc extrusion, discitis with osteomyelitis requiring in emergency surgery
Haufe
[73]		 Prospective study None HSC
(Autologous)		 ns/ns 10 1 No pain improvement - - None
* Cells administered per intravenous infusion as opposed to an intradiscal injection, ** following crossover. Abbreviations: AC; articular cartilage cells, AD; adipose-derived, BM; bone marrow-derived, BMA; bone marrow aspirate, BMC; bone marrow concentrate, BW; body weight, FRI; functional index rating, FU; maximum follow-up time, HA; hyaluronic acid, HSC; hematopoietic stem cells, ITRT; Instituto de Terapia Regenerativa Tissular, IVD; intervertebral disc, JOA; Japanese orthopaedic association, MRI; magnetic resonance imaging, NP; nucleus pulposus, NPS; numerical pain score, ns; not specified, ODI; Oswestry disability index, PEG; polyethylene glycol, PL; platelet lysate, PRP; platelet-rich plasma, QoL; quality of life, RCT: randomized controlled clinical trial SAE; serious adverse events, SF; short form, SVF; stromal vascular fraction, UC; umbilical cord derived, VAS; visual analog (pain) score.
Bone marrow-derived MSC (BM-MSC) as an IVD therapeutic have been examined as an intradiscal injection product in 132 LBP patients [50][52][53][54][55][56][57][58] and as an intravenous infusion product for 31 ankylosing spondylitis patients [51]. In all studies that reported on pain or disability-related outcomes, at least a trend of improvement was observed (Table 1). For example, the non-controlled study of Orozco et al. [55] involving 10 patients resulted in significant VAS, ODI, and short-form 36 (SF-36) measurements. Of particular interest are the two controlled clinical trials. Noriega et al. [53][54] compared the transplantation of 25 × 106 allogenic BM-MSC to a control involving a local paravertebral anesthesia injection. In their 1-year follow-up, the authors recorded a significant improvement in VAS and ODI values compared to baseline at higher rates than the control cohort. A more recent and larger randomized controlled clinical trial (RCT) study by Amirdelfan et al. [58] comparing high (18 × 106) and low (6 × 106) dosages of their allogenic “mesenchymal precursor cells” administration to a saline and hyaluronic acid vehicle control group. Their study showed a significantly enhanced improvement of LBP and ODI for cell-treated cohorts compared to control groups, with higher rates of responders. Though significant, the question can be raised regarding the clinical significance of these findings. Another consideration is underlined by the study of Noriega et al. [53][54], in which they reported a significant improvement in ODI and VAS values; however, according to the authors, this effect stemmed from a 40% portion of responders in their experimental cohort. MRI findings of the BM-MSC studies (Table 1) generally report at least maintenance of disc features, while most suggest a trend of improvement. Specifically, the work of Noriega et al. [53][54] highlighted a significant improvement of Pfirrmann grading for the cell-treated cohort, while their control group had a significant decline in Pfirrmann classification at 12 months compared to baseline. Orozco et al. similarly reported a significant improvement in MRI signal intensity in their treated IVD. On the contrary, the RCT of 60 patients by Amirdelfan et al. [58] failed to report a consistent improvement on MRI outcomes for their cell-treated cohorts. The intravenous infusion of allogenic BM-MSC, as reported by Wang et al. [51], was suggested to alleviate ankylosing spondylitis symptoms as observed through MRI.
Finally, the small case series by Pang et al. [59] applied allogenic umbilical cord-derived MSC (UC-MSC) in two patients. They reported a trend of VAS and ODI improvement 2 years follow-up with one of the two LBP patients presenting enhanced signal intensity on MRI compared to baseline.
Regarding safety outcomes of all MSC types, most of the studies reported no clear serious adverse events, only Amirdelfan et al. [58] reported 8 serious adverse events in their 60 cell-treated patients (1 involving discitis), compared with 4 of 40 patients in their control cohort. These events, however, did not include a severe immunogenic reaction. Of specific interest is the report of Garcia-Sancho et al. [53], complimenting in part the study of Noriega et al. [54], which assessed the influence of HLA matching regarding their allogenic MSC products. They found of the nine degenerative disc disease patients analyzed, none presented with HLA-targeted antibodies matching those of their MSC donors [53]. The lack of immunoreactivity, as suggested by the authors, might be found in the immunomodulatory potential of MSC or the immune privileged and enclosed nature of the IVD, though these suggestions remain highly speculative, especially considering the limited numbers analyzed. On the contrary, a small study by Henriksson et al. [50] applied iron sucrose-labeling to their transplanted BM-MSC for potential cell tracing. In their study, 4 of the 10 patients post MSC transplantation opted to undergo fusion surgery. As part of the fusion surgery, the IVD tissues were explanted, and iron sucrose-labeled cells were detected. Their assays revealed the presence of the transplanted MSC up to 28 months following transplantation. Moreover, additional staining suggested some but not all cells were apoptotic and were in close proximity to SOX9 and type II collagen-positive areas. Notably, however, was the detection of calcium deposits, suggesting early bone formation, in one of the four IVD explants. Again, raising some concern on the potential undesirable differentiation potential of MSC upon transplantation [45]. Though, these deposits were found in both iron sucrose-positive and -negative areas.

4. Nucleus Pulposus and Articular Cartilage-Derived Cells

NP cells form a heterogeneous cell population of native cells residing in the NP and can include highly differentiated rounded NP cells or less undifferentiated progenitor cells [6][74][75]. NP cells are the cells endemic to the IVD, and unlike the previously discussed MSC, they are specially adapted to survive and thrive within the harsh IVD environment [74][76]. Moreover, the chondrogenic NP cells are hallmarked by their high proteoglycan and type II collagen production rates [74]. Naturally, these cells possess the optimal cell type for the regeneration of the NP of the IVD and have been shown to retain in the IVD following transplantation in multiple animal studies [29][77]. Alternatively, other chondrogenic cells types have been suggested, specifically, chondrocytes from articular cartilage as well as hyaline cartilage tissues [44][78]. Similar to NP tissue, other articular cartilage sources are also avascular, and their cells are prone to high proteoglycan and type II collagen production and have thus been suggested and tested as an alternative cell source for IVD repair [37]. Notably, however, the rates of proteoglycan production have been shown to be much lower for articular chondrocytes compared to NP cells [79]. Although both cell types in preclinical studies are suggested to be very potent in supporting IVD repair, their applicability is mainly limited by practical consideration [24]. Specifically, NP and other cartilage sources have low accessibility, and often tissue sources that are obtainable are compromised by disease, age, or trauma [24]. Moreover, these chondrogenic cells types present a limited proliferation capacity and tend to lose their phenotypical features rapidly in vitro [6][80]. Although culture optimization strategies are being explored to enhance the expandability of these cell types [81][82][83].
Clinical studies applying either IVD-derived or articular cartilage-derived cells are less common and small in nature. In total, researchers identified 5 separate studies (Table 1) involving 15 patients treated with articular chondrocytes and 220 treated with IVD-derived chondrocytes. A smaller case series by Mochida et al. [64] transplanted autologous NP cells, reactivated by MSC coculture ex vivo, as a strategy to limit degeneration progression in discs adjacent to fused IVD to prevent adjacent segment disease. Researchers will discuss more on this trial in paragraph 6; nevertheless, overall, the procedure appeared safe and did not show any worsening of the adjacent segments on MRI observations. Similarly, work by Coric et al. [65], which employed juvenile articular chondrocytes, showed in a 1-year follow-up a significant improvement in pain rating as well as ODI and SF-36 outcomes for their 15 treated patients. Moreover, 10 out of 13 patients analyzed through MRI showed improvement on MRI. An RCT study by Meisel et al. [62][63] compared patients undergoing sequestrectomy to a cohort undergoing sequestrectomy followed by transplantation of autologous IVD-derived cells. Their study suggested a trend of improvement in VAS and ODI scores comparing the control to the experimental cohort. Moreover, MRI signal intensity was found significantly higher in the cell-treated cohort than the sequestrectomy-only group. An RCT by Tschugg et al. [60][61] involving autologous IVD-derived cell transplantation was compared to a control cohort only receiving hyaluronic acid-polyethylene glycol carrier. This phase I trial reported no clear evident worsening of disc MRI, but their report did not mention any clear enhancement for the cell-treated group compared to the carrier control group. Finally, a very recent RCT by Beall et al. [66][67] seeded “cells” in an NP allograft and compared the treatment effects to a placebo control and conservative treatment cohort. Conservative treatment recipients were allowed to crossover at 3 months post-transplantation to the allograft cohort if outcomes were unsatisfactory. Their 1-year follow-up study revealed a significant reduction in pain and ODI values for the allograft and crossover group; however, these changes appear similar to the reduction seen in their placebo cohort, resulting in a lack of statistical significance. Nevertheless, a post-hoc stratification analysis by Hunter et al. [68] highlighted that when only patients were considered below the age of 42 years, a statistically significant improvement was observed for mean change in ODI comparing allograft and crossover cohorts separately to the placebo control. Moreover, responder rates for both active groups were significantly higher than the placebo for both ODI (≥10 points) and VAS (≥50%) outcomes. Thereby highlighting the likely need for careful patient selection [84].
Regarding safety outcomes, none of the studies reported any serious adverse events, with the exception of the Vivex Biomedical RCT [66][67], which involved 11 serious adverse events in their allograft cohort and 1 in their crossover group. Six of these were considered potentially related to the treatment and included bacteremia and osteomyelitis.

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Jordy Schol
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