Adipose stem cells for intervertebral disc regeneration: current status and concepts for the future

Nucleus pulposus replacement and regeneration/repair technologies: present status and future prospects

Degenerative disc disease is implicated in the pathogenesis of many painful conditions of the back, chief among which is low back pain. Acute and/or chronic low back pain (A/CLBP) afflicts a large number of people, thus making it a major healthcare issue with concomitant cost ramifications. When conservative treatments for A/CLBP, such as bed rest, anti-inflammatory medications, and physical therapy, prove to be ineffectual, surgical options are recommended. The most popular of these is discectomy followed by fusion. Although there are many reports of good to excellent outcomes with this method, there are concerns, such as long-term adverse biomechanical consequences to adjacent functional spinal unit(s). A surgical option that has been attracting much attention recently is replacement or regeneration/repair of the nucleus pulposus, an approach that holds the prospect of not compromising either mobility or function and causing no adjacent-level injury. There is a sizeable body of literature highlighting this option, comprising in vitro biomechanical studies, finite element analyses, animal-model studies, and limited clinical evaluations. This work is a review of this body of literature and is organized into four parts, with the focus being on replacement technologies, regeneration/repair technologies, and detailed expositions on 14 areas for future study. This review ends with a summary of the salient points made.

Mesenchymal stem cell for prevention and management of intervertebral disc degeneration

Intervertebral disc degeneration (IVD) is a frequent pathological condition. Conservative management often fails, and patients with IVD degeneration may require surgical intervention. Several treatment strategies have been proposed, although only surgical discectomy and arthrodesis have been proved to be predictably effective. The aim of biological strategies is to prevent and manage IVD degeneration, improve the function, the anabolic and reparative capabilities of the nucleus pulposus and annulus fibrosus cells, and inhibit matrix degradation. At present, clinical applications are still in their infancy. Further studies are required to clarify the role of mesenchymal stem cells and gene therapy for the prevention and treatment of IVD degeneration.

Stem cell regeneration of the intervertebral disk

The use of stem cell applications has been explored and aimed at regenerating the intervertebral disk. The microenvironment in which cells of the intervertebral disk reside is harsh; however, researchers have reported on many applications for stem cells, including research aimed at defining and stimulating endogenous stem cell populations, methods to induce stem cell differentiation toward intervertebral disk cell phenotype in vivo, and direct transplantation of stem cells into damaged intervertebral disk to promote transplanted site-dependant differentiation. Successful results have been reported, although limitations remain. This article reviews the current status of stem cell research as applied to the intervertebral disk.

Hyperosmolarity and hypoxia induce chondrogenesis of adipose-derived stem cells in a collagen type 2 hydrogel

Apart from soluble growth factors, various other biophysicochemical cues are known to promote chondrogenesis. Under physiological conditions, cartilage in the joint comprises a hyperosmotic and hypoxic environment. Therefore, in this study, we examined the inductive effects of hyperosmotic and/or hypoxic conditions on adipose stem cells (ASCs) and compared them with conventional TGFβ1-induction. After encapsulation in collagen type II hydrogels and specific induction, ASCs were assessed for viability, proliferation, morphology and chondrogenic differentiation potential. Viability was similar under all conditions, with low proliferative activity. After 4 days, hypoxia and/or hyperosmolarity did not affect round cell morphology, while cells were mainly stretched in the TGFβ1-induced group. At 21 days, the TGFß1-treated group had aggregated into a cell nodule. Hyperosmolarity mimicked this aggregation to a lesser extent, whereas cells under hypoxia stretched out after 21 days, with a combined effect in the hypoxic/hyperosmotic group. Both individual and combined hyperosmotic and/or hypoxic conditions significantly upregulated SOX5, SOX9, COMP and Link-p gene expression compared with the non-induced group, and to similar levels as the TGFβ1-induced group. GAG synthesis in both hydrogel and medium was increased under hypoxic conditions, whereas hyperosmolarity decreased GAG formation in the hydrogels, but increased GAG formation in the medium. We conclude that in a joint mimicking the three-dimensional (3D) micro-environment, a combination of hyperosmolarity and hypoxia is able to induce chondrogenesis to the same extent as TGFβ1. This might lead to an interesting alternative when considering short-term triggering in a one-step surgical procedure for the treatment of cartilaginous defects.

Once fat was fat and that was that: our changing perspectives on adipose tissue

Abstract

Past civilisations saw excess body fat as a symbol of wealth and prosperity as the general population struggled with food shortages and famine. Nowadays it is recognised that obesity is associated with co-morbidities such as cardiovascular disease and diabetes. Our views on the roll of adipose tissue have also changed, from being solely a passive energy store, to an important endocrine organ that modulates metabolism, immunity and satiety. The relationship between increased visceral adiposity and obesity-related co-morbidities has lead to the recognition that variation in fat distribution contributes to ethnic differences in the prevalence of obesity-related diseases. Our current negative view of adipose tissue may change with the use of pluripotent adipose-derived stromal cells, which may lead to future autologous stem cell therapies for bone, muscle, cardiac and cartilage disorders. Here, we briefly review the concepts that adipose tissue is an endocrine organ, that differences in body fat distribution underline the aetiology of obesity-related co-morbidities, and the use of adipose-derived stem cells for future therapies.

The use of poly(L-lactide-co-caprolactone) as a scaffold for adipose stem cells in bone tissue engineering: application in a spinal fusion model

Since the early 1990s, tissue engineering has been heralded as a strategy that may solve problems associated with bone grafting procedures. The original concept of growing bone in the laboratory, however, has proven illusive due to biological, logistic, and regulatory problems. Fat-derived stem cells and synthetic polymers open new, more practicable routes for bone tissue engineering. In this paper, we highlight the potential of poly(L-lactide-co-caprolactone) (PLCL) to serve as a radiolucent scaffold in bone tissue engineering. It appears that PLCL quickly and preferentially binds adipose stem cells (ASCs), which proliferate rapidly and eventually differentiate into the osteogenic phenotype. An in vivo spinal fusion study in a goat model provides a preclinical proof-of-concept for a one-step surgical procedure with ASCs in bone tissue engineering.

Isolation of pig bone marrow mesenchymal stem cells suitable for one-step procedures in chondrogenic regeneration

Large animals such as pigs are good models for skeletal tissue engineering, since they provide physical forces similar to those of humans. Porcine bone marrow mesenchymal stem cells (BMSCs) have shown regenerative capacity similar to those of human BMSCs and can therefore be preclinically applied in settings corresponding to autologous transplantation in patients. Aiming at a one-step procedure for cartilage regeneration with autologous BMSCs, three straightforward isolation methods for BMSCs of Göttingen minipigs were compared. For this purpose, the BMSC fraction was enriched by red blood cell (RBC) lysis, dextran sedimentation or density gradient centrifugation. Isolated BMSCs were evaluated with regard to cell yield, proliferation capacity, phenotype and ability to differentiate to the chondrogenic lineage. Highest cell yields determined at the time of subcultivation were obtained using RBC lysis. In comparison, dextran sedimentation was less efficient but superior to density gradient centrifugation, which yielded significantly lower cell numbers than RBC lysis. The evaluated isolation methods resulted in cultures with equal proliferative capacity, with constant population doubling times of 50-55 h for at least 100 days (approximating to 40 cumulative population doublings) in vitro. Chondrogenic differentiation in micromass pellet cultures was evaluated by glycosaminoglycan quantification, histological staining with Alcian blue and safranin O and immunohistochemical analysis for collagen type II. These evaluations demonstrated that all three isolation methods yielded cells capable of generating cartilaginous tissue in vitro. According to our data, RBC lysis can be used to efficiently isolate porcine BMSCs in a short time frame which would allow for intraoperative one-step procedures in preclinical cartilage regeneration studies.

Human adipose-derived mesenchymal stem cells: direction to a phenotype sharing similarities with the disc, gene expression profiling, and coculture with human annulus cells

Biologic therapies for disc degeneration hold great promise as an emerging concept. Due to ease of harvest and abundance, adipose derived-mesenchymal stem cells (AD-MSC) are a readily available cell source for such therapies. Our objectives in this study were (1) to develop/validate methods to harvest AD-MSC and direct them to a disc-like phenotype by three-dimensional (3D) culture and transforming growth factor (TGF)-beta3 exposure, (2) to assess cell phenotypes with gene expression profiling for these human AD-MSC and annulus cells, and (3) to test whether disc cell-AD-MSC coculture could augment glycosaminoglycan (GAG) production. When AD-MSC were exposed to TGF-beta3, greater extracellular matrix was formed containing types I and II collagen, keratan sulfate, and decorin. Biochemical GAG measurement showed that production was significantly greater in TGF-beta3-treated AD-MSC in 3D culture versus untreated controls (p < 0.05). Gene expression patterns in AD-MSC were compared to annulus cells; 4424 genes were significantly upregulated, and 2290 genes downregulated. Coculture resulted in a 44% greater GAG content compared with AD-MSC or annulus culture alone (p = 0.04). Data indicated that human AD-MSC can successfully be manipulated in 3D culture to express gene products important in the disc, and that coculture of annulus cells with AD-MSC enhances total GAG production.

Regeneration potential and mechanism of bone marrow mesenchymal stem cell transplantation for treating intervertebral disc degeneration

Intervertebral disc degeneration is a primary cause of low back pain and has a high societal cost. The pathological mechanism by which the intervertebral disc degenerates is largely unknown. Cell-based therapy especially using bone marrow mesenchymal stem cells as seeds for transplantation, although still in its infancy, is proving to be a promising, realistic approach to intervertebral disc regeneration. This article reviews current advances regarding regeneration potential in both the in vivo and vitro studies of bone marrow mesenchymal stem cell-based therapy and discusses the up-to-date regeneration mechanisms of stem cell transplantation for treating intervertebral disc degeneration.

Prospective isolation of mesenchymal stem cells from multiple mammalian species using cross-reacting anti-human monoclonal antibodies

Mesenchymal stem cells (MSCs) of human and nonhuman mammalian species are often studied for various applications in regenerative medicine research. These MSCs can be derived from human bone marrow (BM) and identified by their ability to form fibroblast-like colony forming units that develop into stromal like cells when expanded in culture. These cells are characterized by their spindle-shaped morphology, their characteristic phenotype (CD73(+), CD90(+), CD105(+), CD45⁻, and CD34⁻), and their ability to differentiate into cells of the osteogenic, adipogenic, and chondrogenic lineages. However, the identification and purification of MSCs from nonhuman mammalian species is hampered by the lack of suitable monoclonal antibodies (mAb). In this report, primary BM and cultured BM-derived MSCs of human and monkey, goat, sheep, dog, and pig were screened for cross-reactivity using a panel of 43 mAb, of which 22 react with either human BM mononuclear cells or cultured human MSCs. We found 7 mAb with specificity for CD271, MSCA-1 (W8B2 antigen), W4A5, CD56, W3C4 (CD349), W5C4, and 58B1, which showed interspecies cross-reactivity. These mAb proved to be useful for prospective sorting of MSCs from the BM of the 6 mammalian species studied as well as for the characterization of their cultured offspring. Flow sorting with the cross-reacting mAb resulted in up to 2400-fold enrichment of the clonogenic cell fraction (fibroblast-like colony forming units). This study provides an important contribution for the comparative prospective isolation of primary BM-MSCs and the characterization of cultured MSCs from multiple mammalian species for preclinical research.

The effect of ethylene oxide, glow discharge and electron beam on the surface characteristics of poly(L-lactide-co-caprolactone) and the corresponding cellular response of adipose stem cells

Bioabsorbable polymers are increasingly being used in tissue engineering strategies. Despite the knowledge that some sterilization techniques may affect the physical properties of these polymers, this aspect is often overlooked. We speculate that the type of sterilization method used may influence cellular responses by altering the surface characteristics. We cultured adipose stem cells on bioabsorbable poly(l-lactide-co-caprolactone) (PLCL) sheets, sterilized using either ethylene oxide (EO), argon glow discharge (aGD) or electron beam (e-beam). Significantly higher values for surface roughness in the order EO>aGD>e-beam and significant differences in contact angles (EO>e-beam>aGD) and surface energies (aGD>e-beam>EO) were observed. Increased cell attachment and proliferation rates were observed with lower contact angles. The alkaline phosphatase activity was significantly higher for the ethylene oxide sterilized PLCL sheet. In conclusion, the type of sterilization for bioabsorbable polymers should be considered in the design of new scaffolds, since it might affect, or can be used to enhance, the outcome of the tissue engineered construct.

Disc regeneration therapy using marrow mesenchymal cell transplantation: a report of two case studies

STUDY DESIGN

Marrow mesenchymal cells (MSCs) contain stem cells and possess the ability to regenerate bone, cartilage, and fibrous tissues. Here, we applied this regenerative ability to intervertebral disc regeneration therapy in an attempt to develop a new spinal surgery technique.

OBJECTIVE

We analyzed the regenerative restoration ability of autologous MSCs in the markedly degenerated intervertebral discs.

SUMMARY OF BACKGROUND DATA

Fusion for lumbar intervertebral disc instability improves lumbago. However, fused intervertebral discs lack the natural and physiologic functions of intervertebral discs. If intervertebral discs can be regenerated and repaired, then damage to adjacent intervertebral discs can be avoided. We verified the regenerative ability of MSCs by animal studies, and for the first time, performed therapeutic intervertebral disc regeneration therapy in patients and obtained favorable findings.

METHODS

Subjects were 2 women aged 70 and 67 years; both patients had lumbago, leg pain, and numbness. Myelography and magnetic resonance imaging showed lumbar spinal canal stenosis, and radiograph confirmed the vacuum phenomenon with instability. From the ilium of each patient, marrow fluid was collected, and MSCs were cultured using the medium containing autogenous serum. In surgery, fenestration was performed on the stenosed spinal canal and then pieces of collagen sponge containing autologous MSCs were grafted percutaneously to degenerated intervertebral discs.

RESULTS

At 2 years after surgery, radiograph and computed tomography showed improvements in the vacuum phenomenon in both patients. On T2-weighted magnetic resonance imaging, signal intensity of intervertebral discs with cell grafts was high, thus indicating high moisture contents. Roentgenkymography showed that lumbar disc instability improved. Symptom was alleviated in both patients.

CONCLUSION

The intervertebral disc regeneration therapy using MSC brought about favorable results in these 2 cases. It seems to be a promising minimally invasive treatment.

Freshly isolated stromal cells from the infrapatellar fat pad are suitable for a one-step surgical procedure to regenerate cartilage tissue

BACKGROUND AIMS

Stem cell therapies are being evaluated as promising alternatives for cartilage regeneration. We investigated whether stromal vascular fraction cells (SVF) from the infrapatellar (Hoffa) fat pad are suitable for a one-step surgical procedure to treat focal cartilage defects.

METHODS

SVF was harvested from patients undergoing knee arthroplasty (n = 53). Colony-forming unit (CFU) assays, growth kinetics and surface marker profiles were determined, and the chondrogenic differentiation capacity of freshly isolated SVF was assessed after seeding in three-dimensional poly (L-lactic-co-epsilon-caprolactone) scaffolds.

RESULTS

SVF yield per fat pad varied between 0.55 and 16 x 10(6) cells. CFU frequency and population doubling time were 2.6 +/- 0.6% and +/-2 days, respectively. Surface marker profiles matched those of subcutaneous-derived adipose-derived stem cells (ASC). CFU from Hoffa SVF showed differentiation toward osteogenic and adipogenic lineages. Cartilage differentiation was confirmed by up-regulation of the cartilage genes sox9, aggrecan, collagen type II and cartilage oligomeric matrix protein (COMP), collagen II immunostaining, Alcian Blue staining and glycosaminoglycan production. Compared with passaged cells, SVF showed at least similar chondrogenic potential.

CONCLUSIONS

This study demonstrates that SVF cells from the infrapatellar fat pad are suitable for future application in a one-step surgical procedure to regenerate cartilage tissue. SVF shows similar favorable characteristics as cultured ASC, and chondrogenic differentiation even appears to be slightly better. However, because of variable harvesting volumes and yields, SVF from the infrapatellar fat pad might only be applicable for treatment of small focal cartilage defects, whereas for larger osteoarthritic defects subcutaneous adipose tissue depot would be preferable.

Mechanical profiling of intervertebral discs

Despite recent advances in imaging diagnostic technology and additional treatment options our ability to prevent or inhibit discogenic back pain has not drastically improved. The challenge of linking early degenerative patterns to dysfunction and pain remains. Using a novel material testing device designated the tissue diagnostic instrument (TDI) we measured the local stiffness and strain energy absorption in the radial direction of 13 intact intervertebral discs; effectively generating a mechanical profile of each disc. Prior to measuring mechanical properties, an MR image was taken of each spine segment and the discs were radiologically scored according to the Pfirrmann scale. After testing, a sagittal portion of each L1-L2 disc was excised from each of four spines for histology. No significant correlations were found between Pfirrmann grade and mechanical data. However, polarized light microscopy images of disc sections indicated correlations between local tissue modulus measured with the TDI and the clarity and density of lamellar striations.

Repair, regenerative and supportive therapies of the annulus fibrosus: achievements and challenges

Lumbar discectomy is a very effective therapy for neurological decompression in patients suffering from sciatica due to hernia nuclei pulposus. However, high recurrence rates and persisting post-operative low back pain in these patients require serious attention. In the past decade, tissue engineering strategies have been developed mainly targeted to the regeneration of the nucleus pulposus (NP) of the intervertebral disc. Accompanying techniques that deal with the damaged annulus fibrous are now increasingly recognised as mandatory in order to prevent re-herniation to increase the potential of NP repair and to confine NP replacement therapies. In the current review, the requirements, achievements and challenges in this quickly emerging field of research are discussed.

Future perspectives of cell-based therapy for intervertebral disc disease

Intervertebral disc degeneration is a primary cause of low back pain and has a high societal cost. Research on cell-based therapies for intervertebral disc disease is emerging, along with the interest in biological therapy to treat disc disease without reducing the mobility of the spinal motion segment. Results from animal models have shown promising results under limited conditions; however, future studies are needed to optimise efficacy, methodology, and safety. To advance research on cell-based therapy for intervertebral disc disease, a better understanding of the phenotype and differentiation of disc cells and of their microenvironment is essential. This article reviews current concepts in cell-based therapy for intervertebral disc disease, with updates on potential cell sources tested primarily using animal models, and discusses the hurdles to clinical application. Future perspectives for cell-based therapies for intervertebral disc disease are also discussed.