Clinical Potential and Current Progress of Dental Pulp Stem Cells for Various Systemic Diseases in Regenerative Medicine: A Concise Review
Abstract
:1. Introduction
2. Therapeutic Potential of DPSCs in Various Systemic Diseases
2.1. Spinal Cord Injury (SCI)
2.2. Parkinson’s Disease (PD)
2.3. Alzheimer’s Disease (AD)
2.4. Cerebral Ischemia
2.5. Myocardial Infarction
2.6. Muscular Dystrophy
2.7. Diabetes
2.8. Liver Disease
2.9. Eye Disease
2.10. Immune Disease
2.11. Oral Diseases
3. Clinical Application of DPSCs
4. Current Limitations and Perspectives
5. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Disease | Cells | Study Model (Application Method) | Outcome | Ref. |
---|---|---|---|---|
Spinal cord injury (SCI) | Human DPSCs, SHED (stem cells from human exfoliated deciduous teeth) | Transplantation into a completely transected rat SCI model | DPSCs and SHED had neuroregenerative activities including inhibition of apoptosis of neurons, astrocytes, and oligodendrocytes, promoted the regeneration of transected axons, and replaced lost cells that fulfill many requirements for functional recovery after SCI. | [31] |
SHED, neural induced SHED (iSHED) | Injection into the spinal cord lesions of rat acute contused SCI model | Transplanted SHED and iSHED showed neuronal and glial differentiation and displayed significant locomotor functional recovery. | [34] | |
Human DPSCs | Transplanted into completely transected rat spinal cord | DPSCs presented tissue regenerative capability after SCI through their immunomodulatory, differentiation, and protection capacity. | [35] | |
SHED | Transplanted into completely injured rat spinal cord | The acute transplantation of SHED reduces early neuronal apoptosis, contributing to tissue and motor neuron preservation and hind limb functional recovery. | [36] | |
Parkinson’s disease (PD) | SHED | Intrastriatal transplantation of SHED and SHED-derived spheres in Parkinsonian rats | SHED and SHED-derived spheres differentiated into dopaminergic neurons and ameliorated behavioral impairment. | [37] |
SHED | Intrastriatal transplantation of SHED and SHED-derived dopaminergic neuron-like cells (dSHED) in Parkinsonian rats | Engrafted dSHEDs survived in the striatum of Parkinsonian rats, improved the dopamine level more efficiently than engrafted undifferentiated SHED, and promoted recovery from neurological deficits. | [38] | |
Human DPSCs | MPP+ or rotenone-induced in vitro model of PD; indirect co-culture system with mesencephalic cell cultures | DPSCs showed a protective effect on dopamine neurons; dopamine uptake, and an increased number of spared tyrosinehydroxylase (TH)+ cells. | [39] | |
Alzheimer’s disease (AD) | Rat dental pulp cells | In vitro model of AD | The co-culture with dental pulp cells significantly attenuated 6-hydroxydopamine and Abeta(1-42)-induced toxicity in primary cultures of hippocampal neurons. | [40] |
Human DPSCs | In vitro model of AD established by okadaic acid (OA)-induced damage to human neuroblastoma cell line | DPSCs caused a significant increase in the viability and a decrease in apoptosis of AD model cells and phosphorylation at Ser 396 of Tau protein was significantly suppressed. | [41] | |
Cerebral ischemia | CD31−/CD146− side population (SP) cells from porcine dental pulp | Transplanted into brain of middle cerebral artery occlusion rat | The cells promoted migration and differentiation of the endogenous neuronal progenitor cells, induced vasculogenesis, and ameliorated ischemic brain injury. | [42] |
Human DPSCs | Intracerebral transplantation of human DPSCs 24 h following focal cerebral ischemia in rat model | Human DPSC treatment enhanced functional recovery of post-stroke sensorimotor deficits. | [43] | |
Human DPSCs | Intravenous transplantation of human DPSCs in a rat stroke model | DPSCs had a better effect on infarct size and significantly decreased reactive gliosis compared with bone-marrow-derived MSCs. | [44] | |
Rat DPSCs | Intravenous administration in rat model of focal cerebral ischemia | DPSCs migrated into the boundary of ischemic areas and expressed neural specific markers, reducing infarct volume and cerebral edema. | [45] | |
Myocardial Infarction | Human DPSCs | Intramyocardial injection into nude rats with acute myocardial infarction | Cell-treated animals showed an improvement in cardiac function, observed by changes in anterior wall thickening, and a reduction in infarct size; angiogenesis was increased. | [46] |
Muscular dystrophy | SHED | Systemic or intramuscular transplantation of SHED in golden retriever muscular dystrophy dogs | Donor SHED can engraft, differentiate, and persist in the host muscle. Systemic multiple deliveries seemed more effective than local injections. | [47] |
Human DPSCs | Intramuscular injection of pre-differentiated DPSCs into mdx/SCID mice, an immune-compromised animal model of Duchenne muscular dystrophy | DPSCs engrafted within the host muscle, promoted angiogenesis, and reduced fibrosis. | [48] | |
Human dental pulp pluripotent-like stem cells (DPPSC) | DPPSC injection in dystrophic mice | DPPSC differentiated into both endothelial cells and smooth muscle cells and contributed to myogenic regeneration. | [49] | |
Diabetes | Human DPSCs, SHED | Transplantation of islet-like cell clusters (ICCs) derived from SHED into streptozotocin-induced diabetic mice | Mice transplanted with macro-capsules containing ICCs were restored to normoglycemia. | [50] |
Mouse DPSCs | Endovenous transplantation of DPSCs into streptozotocin-induced diabetes type 1 model | Transplanted DPSCs were confirmed in or surrounding pancreatic islets and DPSC transplantation improved pancreatic damage, renal function, and painful neuropathy. | [51] | |
Rat DPSCs | Transplantation into the unilateral hind limb skeletal muscles of diabetic rat | DPSC transplantation improved sciatic nerve conduction velocity and sciatic nerve blood flow, ameliorated sural nerve axonal circularity, and decreased the macrophages in diabetic sciatic nerves. | [52] | |
Human DPSCs | Intravenous or intramuscular transplantation of DPSCs into streptozotocin -induced neuropathic rats | DPSC transplantation through both routes was beneficial for the retrieval of neuropathic parameters of diabetic neuropathy. | [53] | |
Liver disease | SHED | Intrasplenic transplantation into the liver dysfunction of carbon tetrachloride-treated mice | Transplanted SHED directly transformed into hepatocytes, improved hepatic dysfunction, and led to anti-fibrotic and anti-inflammatory effects in the recipient livers. | [54] |
Human DPSCs | Transplantation of hepatically differentiated DPSCs into carbon tetrachloride-treated mice | The combination of melatonin and hDPSC significantly suppressed liver fibrosis and restored alanine transaminase, aspartate transaminase, and ammonia levels. | [55] | |
Human DPSCs | Transplantation of hepatically differentiated DPSCs into carbon tetrachloride-treated mice | The combination of hDPSCs and PIN1 inhibitor juglone into CCl4-injured mice significantly suppressed liver fibrosis and restored serum levels of alanine transaminase, aspartate transaminase, and ammonia. | [56] | |
Eye disease | Human DPSCs | Keratocyte differentiated DPSCs were injected into mouse corneal stroma | Human DPSCs produced corneal stromal extracellular matrix and did not affect corneal transparency or induce immunological rejection. | [57] |
SHED sheet | Transplantation onto the corneal bed in rabbit model of limbal stem cell deficiency | Transplantation of a tissue-engineered human undifferentiated immature DPSC sheet was successful for the reconstruction of corneal epithelium. | [58] | |
Human DPSCs | Contact lenses pre-seeded with DPSCs were transferred onto corneas | DPSCs transdifferentiated into corneal epithelial progenitors and established a barrier to the invasion of the cornea. | [59] | |
Human DPSCs | Intravitreal transplantation in rodent model of glaucoma | DPSC provided significant protection from retinal ganglion cell (RGC) loss and preserved visual function. | [60] | |
Immune disease | SHED | Systemic transplantation to SLE-like murine model | SHED transplantation was capable of effectively reversing systemic lupus erythematosus (SLE)-associated disorders in SLE-like mice. | [61] |
Oral disease | Canine CD105+ DPSCs | Transplantation into an adult canine model of pulpectomy | Complete pulp regeneration with neurogenesis and vasculogenesis occurred after transplantation of CD105+ DPSCs in pulpectomized root canals in canines. | [62] |
SHED | Injection into full-length human root canals model of pulpectomy | SHED survive and differentiate into odontoblasts when transplanted into full-length human root canals with injectable scaffolds. | [63] | |
Canine DPSCs | Implantation into canine periodontitis model | Regeneration of cementum, bone, and periodontal ligament was observed. | [64] | |
Canine DPSCs, deciduous tooth stem cells | Transplantation into canine alveolar bone atrophy model | Regeneration of well-formed mature bone was observed and dental implants were successfully installed in the regenerated bone. | [21] |
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Yamada, Y.; Nakamura-Yamada, S.; Kusano, K.; Baba, S. Clinical Potential and Current Progress of Dental Pulp Stem Cells for Various Systemic Diseases in Regenerative Medicine: A Concise Review. Int. J. Mol. Sci. 2019, 20, 1132. https://doi.org/10.3390/ijms20051132
Yamada Y, Nakamura-Yamada S, Kusano K, Baba S. Clinical Potential and Current Progress of Dental Pulp Stem Cells for Various Systemic Diseases in Regenerative Medicine: A Concise Review. International Journal of Molecular Sciences. 2019; 20(5):1132. https://doi.org/10.3390/ijms20051132
Chicago/Turabian StyleYamada, Yoichi, Sayaka Nakamura-Yamada, Kaoru Kusano, and Shunsuke Baba. 2019. "Clinical Potential and Current Progress of Dental Pulp Stem Cells for Various Systemic Diseases in Regenerative Medicine: A Concise Review" International Journal of Molecular Sciences 20, no. 5: 1132. https://doi.org/10.3390/ijms20051132
APA StyleYamada, Y., Nakamura-Yamada, S., Kusano, K., & Baba, S. (2019). Clinical Potential and Current Progress of Dental Pulp Stem Cells for Various Systemic Diseases in Regenerative Medicine: A Concise Review. International Journal of Molecular Sciences, 20(5), 1132. https://doi.org/10.3390/ijms20051132