Intervertebral Disc Degeneration: The Role and Evidence for Non–Stem-Cell-Based Regenerative Therapies

Anatomy and Function of Intervertebral Discs

Often a multifactorial condition, LBP can be categorized by the origin of the pain. A common cause includes intervertebral disc (IVD) degeneration, a distinct category of back pain that primarily consists of nociceptive and neuropathic pain. Other commonly used terms to describe this condition include discogenic disease or axial back pain.^6–9 The IVD lies between the vertebral bodies, serves as the articulating surface between 2 adjacent vertebral bodies, and is the largest avascular tissue in the body.¹⁰ There is a total of 23 IVD (6 cervical, 12 thoracic, and 5 lumbar), which account for about 20%–30% of the total length of the spine.¹¹ The IVD is a complex structure that is composed of 3 distinct components: the inner nucleus pulposus (NP), the outer annulus fibrosus (AF), and the cartilaginous endplates (CEP). The inner NP is a gel-like structure primarily consisting of type II collagen and large proteoglycans that retain water to help absorb and disperse compressive loads exerted on the spine.¹¹ Surrounding the NP is a fibrocartilaginous structure known as the AF, which is composed of inner and outer concentric layers of collagen fibers with alternating angles that account for its tensile strength.¹² The final component of the IVD is the CEP, which are thin layers of hyaline cartilage measuring approximately 600-μm thick positioned on the superior and inferior surfaces of the IVD, between the NP and VEP, also known as ring apophysis.¹⁰ It is important to note that the VEP and CEP are two distinct structures, and only the CEP is part of the IVD complex. In addition to functioning as a mechanical barrier between the vertebral bodies and NP, the CEP is also the principal means for nutrient transport into the disc from the adjacent vasculature.^10,13

The IVD is largely avascular with a limited number of microvessels present during adulthood. In the early stages of skeletal development, the vascular channels transverse the CEP and supply the majority of the IVD, with the exception of the NP. As the skeletal body continues to mature, the vessels start to retract and migrate towards the outer parts of the AF and the bone-cartilage junction.¹¹ At this stage, the inner AF and NP rely on diffusion for nutrient consumption.

The initial onset of discogenic disease can often be asymptomatic, as subtle changes in the matrix of the nucleus pulposus (NP) and annulus fibrosus (AF) take shape.¹⁴ As a result, pain in discogenic disease is more often definitively seen with late IVD degeneration, a stage at which imaging can assist with diagnosis of disc-space narrowing, internuclear calcification, osteophyte formation, and endplate sclerosis.^15–17 The flexibility of the spinal column can be credited to the elastic IVD that lie between solid vertebrae. Mechanical forces can elicit flexion, extension, lateral, and rotational loads upon the spine. Excessive magnitude, vectors, or duration of forces can cause disc degeneration, because structural changes related to the matrix within IVD can malfunction, ultimately compromising the mechanical properties of the spinal column altogether.^18,19

Mechanisms of IVD Degeneration

Disc degeneration is broadly understood to be a product of an imbalance between matrix anabolism and catabolism. Excess catabolic processes result in activation of proinflammatory cell signaling has been shown to weaken and replace matrix and collagenous components of the NP and AF. Therefore, intervention of disc cell necrosis and/or apoptosis has become the mainstay of many therapeutic modalities within this field of management. This can be achieved through upregulation of the underlying proteins and cytokines involved in stimulating disc cell growth, or replacement of necrotic cells in late-stage catabolism.^20,21

Protein Growth Factors in IVD Homeostasis

To understand the treatment modalities involved in discogenic pain, a review of the underlying molecular components of anabolism and catabolism is necessary. At the core of this process lies proteins and growth factors. Some of the key components of this molecular cascade will be highlighted in this section.

Bone morphogenetic protein-2 (BMP-2) stimulates synthesis of the disc extracellular matrix.²² As a member of the transforming growth factor β (TGF-β) superfamily of proteins, it helps regulate bone and cartilage formation. With this role, BMP-2 is often targeted for therapeutic intervention in degenerative disc disease.^23–26 Animal models have shown that proteins in the BMP class can upregulate proteoglycan synthesis; specifically, the use of recombinant BMP-2 on human disc cells has resulted in increased collagen and proteoglycan production within the nucleus pulposus.^27–29

Growth differentiation factor (GDF) is a member of the BMP family. Whereas many members of this family promote activity at the bone, GDF has been shown to induce the formation of cartilage and tendon tissue instead.³⁰ In chondrocytes and NP cells in vitro, GDF has been shown to have the anabolic effects of upregulated proteoglycan (PG) and collagen production in NP and AF cells.^31,32 However, GDF has properties to equally promote catabolic processes via signaling pathways. The GDF signaling begins at heteromeric transmembrane serine-threonine kinase receptor complexes with type I and type II receptor molecules.³³ Receptor binding ultimately leads to activation of SMAD kinase pathways. With subsequent downstream integrin activation, this cascade promotes inflammatory cytokine signaling. The GDF can provide an important link between the anabolic and catabolic processes of disc degeneration, often making it a well-studied target for therapeutic interventions of discogenic pain. The balance between anabolic and catabolic processes suggests GDF is central to homeostatic maintenance of the IVD.³⁴

The TGF-β family was initially described³⁵ in 1983. The first member of this group of cell regulatory proteins, TGF-β1, is a secreted polypeptide involved in proliferation, growth, and cell differentiation.³⁶ Similar to previous in vitro models of GDF, studies of TGF-β activation have shown its anabolic effects such as increased PGs and type II collagen deposition that help maintain bone homeostasis, promote tissue repair, and regulate chondrocyte activity.^37–39 TGF-β activation is shown to be mediated by α_v and multiple β integrin subunits.^40,41 Similar integrin expression in cells of the NP suggest how integrin-mediated activation of TGF-β is important for IVD homeostasis and anabolic processes.^42,43 Hiyama et al⁴⁴ related the downstream signaling effects of TGF-β with BMP-2 and found that both regulate β1,3-glucuronosyl transferase-1 expression and chondroitin sulfate synthesis in NP cells, promoting anabolic processes within matrix cells. TGF-β3 is a specific growth factor that has been shown to play a role in transformation of IVD structure via cell differentiation.⁴⁵ In vitro models with supplemented TGF-β3 were associated with elevated levels of activated ERK1/2 and enhanced expression of receptors TGF-βRI and TGF-βRII, which showed elevated expression of matrix genes and PG incorporation.⁴⁶

Cessation of the Catabolic Cascade and Inflammation

The balance between anabolic and catabolic processes allows for multiple treatment approaches in IVD. Whereas growth factors are the most commonly approached target in literature, cessation of the catabolic cascade is an alternative to achieve anticatabolic effects that achieve disc regeneration and maintain homeostasis.

Much of disc degeneration can be attributed to destruction of matrix components via overexpression of proteases such as matrix metalloproteinases and ADAMTS. Cytokines are responsible for activation and regulation of these proteases and their subsequent effects.⁴⁷ Tumor necrosis factor-α (TNF-α) is a proinflammatory cytokine that is upregulated in IVD degeneration, and its effect has been well studied in vitro. Wang et al⁴⁸ showed that a blockade of TNF-α–induced upregulation of ADAMTS-4 and ADAMTS-5 reversed cytokine-mediated collagen degradation in human IVD in vitro. Tobinick and Davoodifar⁴⁹ studied Etanercept, a TNF-α antagonist, and found a significant improvement in discogenic pain in patients at all follow-up intervals (P < .0001). The cytokine interleukin-1 (IL-1) acts similarly to TNF-α as a proinflammatory agent involved in cell apoptosis. Therapy focused on blocking IL-1 is widely studied as a means to help prevent inflammation-mediated damage that leads to disc degeneration.⁵⁰ Hoyland et al⁵¹ were able to investigate and compare TNF-α and IL-1 on matrix degeneration and found that inhibition of IL-1 was more effective than inhibition of TNF-α in reducing degradation in normal or degenerated discs.

Another therapeutic target of the catabolic cascade is platelet-derived growth factor (PDGF). Presciutti et al⁵² showed that PDGF is associated with inhibited cell apoptosis, cell proliferation, matrix production, and messenger RNA expression of critical extracellular matrix genes when studied in vitro. Similar in vitro studies showed PDGF stimulated both PG synthesis in NP cells and IVD cell proliferation.^53,54

With the growing literature support for growth factor administration for improved outcomes in degenerated IVD and matrix homeostasis, administration of PRP has become a mainstay of study and clinical therapeutic intervention in recent years.⁵⁵ PRP is an autologous blood concentrate and often directly administered into the IVD for management of LBP. The advantage of PRP is its concentrated mix of growth factors and cytokines, therefore promoting tissue regeneration and repair.^56,57 The use of PRP in IVD repair has been widely studied in vitro, with promising results. Overall, in vitro studies showed PRP was effective at stimulating cell proliferation and increased PG and collagen synthesis.^58–60 The anti-inflammatory effects of PRP were also highlighted by recent studies. PRP was found to be associated with suppressed aggrecan and type II collagen, stimulation of matrix metalloproteinases-3 and cyclooxygenase-2 expression, and diminished cytokine (IL-1, TNF-α) response and gene expression.^61–63

Prolotherapy in Intradiscal Pain Management

Prolotherapy for discogenic pain management involves injection of a solution that creates an inflammatory response to repair connective tissue. Commonly used agents include hypertonic dextrose, phenol, or sodium morrhuate. Although these solutions are in the same class of therapy, each uses different mechanisms to elicit their desired response. Dextrose, often the mainstay of prolotherapy due to its well-studied properties of water solubility and safe entry, is an osmotic agent that irritates local tissue to recruit inflammatory cells and the subsequent cascade. Irritants such as phenol damage cell membranes, whereas chemotactic agents such as sodium morrhuate can directly activate the inflammatory cascade.^71–73 The literature examining intradiscal prolotherapy for spine pain includes 2 studies, both reporting positive results.

Derby et al⁷⁴ performed a pilot study comparing intradiscal electrothermal treatment (IDET) with dextrose intradiscal injection therapy. A total of 109 patients with discogenic back pain were followed for 6–18 months after a single procedure. Pain relief was statistically significant for both procedures, marginally better for injections (2.2 VAS) than for IDET (1.27 VAS; P = .01). Postoperative satisfaction surveys showed that patients receiving injections were significantly more satisfied, and 35.8% of patients in the IDET group actually reported worsening of pain, whereas no patients receiving dextrose reported this. However, postprocedure flare-ups were more frequent in the restorative injection group (81%) than after IDET (68.9%) and were more severe (VAS: 7.9 and 6.1, respectively). Multiple outcome measures in this study point towards biologic intradiscal intervention having similar clinical efficacy as IDET, with an improved cost-benefit ratio. Notably, the intradiscal intervention used was also a mixture of hypertonic dextrose, glucosamine/chondroitin, and dimethylsulfoxide; therefore, a direct analysis of prolotherapy was more difficult to establish from this study.

Miller et al⁷⁵ observed 76 patients in a prospective case series receiving biweekly hypertonic dextrose injections for degenerative disc disease. Each patient was injected 3.5 times on average. Of the patients, 43.4% reported sustained improvement and an average improvement in NPS of 71% at 18 months, compared with pretreatment measures. Similar to Derby et al,⁷⁴ a lack of placebo control and randomization is notable in this study. Degenerative disc disease should also be monitored with longer follow-up times to reflect its chronic disease course.

The efficacy of prolotherapy as an intervention for discogenic disease has much more room for analysis within the literature. Two existing studies suggest that intradiscal injection of dextrose solutions may be useful in the management of pain arising from degenerative disc disease. Randomized controlled trials and trials with placebo groups are still necessary to evaluate this further.

Application of Radiopaque Gelified Ethanol for Clinical Studies of Discogenic Disease

As the utility of minimally invasive percutaneous treatment in intervertebral discogenic pain grows, one modality recently made available is radiopaque gelified ethanol (DiscoGel, Gelscom, France). Introduced in 2007, DiscoGel is a sterile viscous intradiscal solution consisting of gelified ethanol with tungsten in suspension. More viscous than absolute ethanol, it is used as a treatment for pain from lumbar discs that fail conservative treatment with an absence of neurological deficit. As DiscoGel is injected into the nucleus pulposus, it decompresses the intradiscal space. Tungsten is added to slow the progression of the gel in the disc, leading to a more controlled substance diffusion. The resulting osmotic gradient allows for water to shift from the periphery to the center of the disc, facilitating disc decompression and reduction of intradiscal pressure.^76–78

Recent studies have emerged specifically addressing the efficacy of DiscoGel in LBP management. Prospective observational studies currently make up the bulk of this research domain. Stagni et al⁷⁹ performed a single DiscoGel chemonucleolysis injection on patients with lumbar disc herniation. A total of 32 individuals met the criteria, which specifically targeted patients who had poor therapeutic outcome following intradiscal oxygen-ozone (O₂-O₃) therapy performed at least 6 months before DiscoGel treatment. The O₂-O₃ chemonucleolysis is an alternative minimally invasive treatment with the best cost-benefit ratio and lowest complication rate (<0.1%) in treatment of herniated discs.⁸⁰ The treatment was successful (pain lessened) in 24 of 32 patients (75%) after 6 months. Of the remaining 25%, recourse to surgery was seen in 3 cases (9.3%). Notably, no difference was observed between patients who underwent discolysis in more than 1 level and those treated at a single level. This study found that their results with DiscoGel are comparable to therapeutic success rates of O₂-O₃ chemonucleolysis, suggesting its efficacy in cases refractory to O₂-O₃ therapy. A randomized controlled trial is still necessary to compare these modalities and their prognosis directly, with longer follow-up intervals.

A prospective observational study was performed by Kuhelj et al⁸¹ in 2019, using DiscoGel injection in lumbar disc herniations. Among their 82 initial participants, 89.8% of study respondents had a significant reduction in VAS after 1 month, with mean VAS scores of 8.5→4.5 for the lumbar spine group (P < .001). Of the patients, 96.6% were seriously to moderately disabled prior to treatment, which reduced postprocedurally to 30% after 1 year. One major drawback of this study, however, was a poor rate of follow-up (25% of patients). This study also highlights that many trials within radiopaque gelified ethanol injection are focused on immediate or short-term follow-up, reporting results up to 1 year. Discal degeneration is a chronic, progressive disease that has permanent effects on quality of life, justifying the need for further studies to establish a care model for long-term results.

Hashemi et al⁸² presented a prospective observational study comparing DiscoGel with percutaneous laser disc decompression (PLDD) in patients with LBP and radiculopathy secondary to lumbar IVD herniation, the first study of its kind. A total of 72 participants with either intervention were followed up to 12 months. Overall, a significant reduction in mean NRS of the preoperative total cohort (8.0) to DiscoGel (4.3) and PLDD groups (4.2; P = .001). Mean ODI scores also showed a significant decrease from the total cohort (81.25%) to the DiscoGel (41.14%) and PLDD groups (52.86%; P = .001). This study began to offer a more direct comparison between current treatment modalities but still lacked randomization and control. Hashemi et al⁸² further suggested that a comparison with conservative treatment would aid in understanding long-term efficacy.

A randomized, double-blind controlled trial was performed by Papadopolous et al⁸³ in 2020. This study compared DiscoGel (group A) with DiscoGel in combination with pulsed radiofrequency (group B). During the follow-up period, a significant difference in pain (VAS) was found at 6 and 12 months. Overall, group B showed a statistically significant difference compared with group A regarding the study's secondary objectives, such as the Roland-Morris Disability Questionnaire, Lanss score, and quality of life (EQ-5D). Although this study monitored progress up to 12 months with a small sample size, the randomization marks it as the first of its kind regarding radiopaque gelified ethanol for intradiscal disease. The suggestion of improved outcomes through augmentation of DiscoGel treatment with pulsed radiofrequency should be studied in the future with prolonged follow-up intervals.

The application of radiopaque gelified ethanol has grown over the past decade. Clinical studies continue to emerge, but the intervention still lacks a library of randomized controlled trials necessary to evaluate the long-term treatment advantages and efficacy as a minimally invasive percutaneous treatment.

Evidence of Safety in Intradiscal Injection

As the application of interventional discogenic pain management modalities grows, follow-up studies have been used to monitor compilations or side effects (Table 2). Potential risks related to intradiscal injection procedures include bleeding, pain at the injection site, osteomyelitis/discitis, nerve injury, or allergic reactions to steroids or dye.^84,85 Early evidence suggests positive outcomes with low adverse effects across a variety of procedure types and biologics, particularly when compared with surgical alternatives across similar patient populations. Orozco et al⁸⁶ performed a pilot study in 2011 on 10 patients with chronic degenerative disc disease treated with autologous expanded bone marrow mesenchymal stem cells (MSC) injected into the NP. Significant improvements were seen in pain (VAS) and disability (ODI) at the 3-, 6-, and 12-month follow-up periods (P < .001), with no major adverse effects recorded. Despite this study showing no change in disc height on MRI follow-up, there was increased T2 signal within the disc at 1-year follow-up, suggesting this modality promoted disc hydration alongside a favorable side effect profile.

Phase 1 studies allow monitoring of safety and efficacy for intradiscal injection across a variety of treatment arms and biologics. Tschugg et al⁸⁷ performed a phase 1 study in 2016 assessing the safety and efficacy of an autologous disk chondrocyte transplantation of Novocart Disc Plus (NDplus; Aesculap, Tuttlingen, Germany) across 24 patients while using immunological markers as a treatment arm. No indications of harmful material extrusion or immunological consequences were observed across the 6-week follow-up period. C-reactive protein and IL-6 markers were not significantly elevated at any point, and there were no imaging abnormalities such as fractures, significant foraminal stenosis or degenerative spinal stenosis. Kumar et al⁸⁸ reflected similar outcomes in their single-arm phase 1 clinical trial in 2017, which assessed the safety and tolerability of intradiscal implantation of adipose tissue–derived MSCs (AT-MSCs) for chronic discogenic LBP. Ten patients composed 2 groups with low- or high-dose AT-MSCs and hyaluronic acid derivative intradiscal injection. No procedure or stem cell–related adverse events occurred during the 1-year follow-up period, whereas VAS (pain), ODI (disability), and SF-36 scores significantly improved in both groups (P = .002). In 2012, Coric et al⁸⁹ performed a single-arm prospective cohort study evaluating the safety of NuQu allogeneic juvenile chondrocytes delivered percutaneously for the treatment of lumbar spondylosis with mechanical LBP in 15 patients. Mean ODI, NRS, and SF-36 summaries all improved significantly from baseline at a 12-month follow-up, and 8 patients sustained radiological improvement in disc contour and height at 12 months. No patient experienced neurological deterioration, disc infections, or serious or unexpected adverse events during the follow-up period.

The evidence of safety across interventional administration of allogeneic cell sources is growing. Early studies show encouraging outcomes, particularly when compared with side effect profiles and risks of alternative surgical modalities available. Randomized controlled trials across prolonged follow-up periods exceeding 1 year would help evaluate the long-term safety of minimally invasive percutaneous modalities and autologous and allogeneic cell sources.