Background:

DRJ

Dent Res J

Dental Research Journal

1735-3327 2008-0255

Medknow Publications Pvt Ltd

India

DRJ-11-244

Original Article

A modified efficient method for dental pulp stem cell isolation

Raoof

Maryam

Yaghoobi

Mohammad M

Derakhshani

Ali

Kamal-abadi

Ali M

Ebrahimi

Behnam

Abbasnejad

Mehdi

Shokouhinejad

Noushin

Department of Endodontics, Kerman Oral and Dental Diseases Research Center, Kerman University of Medical Science, Kerman, Iran Department of Biotechnology, Institute of Science and High Technology and Environmental Sciences, Graduate University of Advanced Technology, Kerman, Iran Department of Pathology, Stem Cell Research Center, Kerman University of Medical Sciences, Kerman, Iran Private practice, Tehran, Iran Department of Biotechnology, Institute of Science and High Technology and Environmental Sciences, Graduate University of Advanced Technology, Kerman, Iran Department of Biology, Shahid Bahonar University of Kerman, Kerman, Iran Department of Endodontics, School of Dentistry/Dental Research Center, Tehran University of Medical Sciences, and Iranian Center for Endodontic Research, Tehran, Iran

Address for correspondence:Ali Derakhshani, Department of Pathology, Stem Cell Research Center, Kerman University of Medical Sciences, Kerman, Iran derakhshan_a64@yahoo.com

Mar–Apr 2014

11 2 244 250

2014

This is an open-access article distributed under the terms of the Creative Commons Attribution-Noncommercial-Share Alike 3.0 Unported, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Background:

Dental pulp stem cells can be used in regenerative endodontic therapy. The aim of this study was to introduce an efficient method for dental pulp stem cells isolation.

Materials and Methods:

In this in-vitro study, 60 extracted human third molars were split and pulp tissue was extracted. Dental pulp stem cells were isolated by the following three different methods: (1) digestion of pulp by collagenase/dispase enzyme and culture of the released cells; (2) outgrowth of the cells by culture of undigested pulp pieces; (3) digestion of pulp tissue pieces and fixing them. The cells were cultured in minimum essential medium alpha modification (αMEM) medium supplemented with 20% fetal bovine serum(FBS) in humid 37°C incubator with 5% CO ₂. The markers of stem cells were studied by reverse transcriptase polymerase chain reaction (PCR). The student t-test was used for comparing the means of independent groups. P <0.05 was considered as significant.

Results:

The results indicated that by the first method a few cell colonies with homogenous morphology were detectable after 4 days, while in the outgrowth method more time was needed (10-12 days) to allow sufficient numbers of heterogeneous phenotype stem cells to migrate out of tissue. Interestingly, with the improved third method, we obtained stem cells successfully with about 60% efficiency after 2 days. The results of RT-PCR suggested the expression of Nanog, Oct-4, and Nucleostemin markers in the isolated cells from dental pulps.

Conclusion:

This study proposes a new method with high efficacy to obtain dental pulp stem cells in a short time.

Dental pulp stem cells isolation method molar

</sec> <sec> <title>Introduction

Pulp necrosis and interruption of tooth development, which result in incompletely formed roots with wide open apices, reduced root length, and fragile thin dentinal walls, may be the consequences of physical trauma or endodontic infection of a tooth with an immature apex. ¹Apexification is a treatment used to seal an open apex by inducing a calcified barrier at the root. Calcium hydroxide and mineral trioxide aggregate (MTA) are the most widely accepted materials for apexification procedures, but none of them is able to stimulate regeneration of pulp tissue and continued root development, so a root with considerably thin walls at increased risk of fracture remains and may lead eventually to loss of the tooth. ²Tooth loss has long been associated with accelerated aging and has considerable negative consequences such as vertical and horizontal positional changes. ³One of the most common traditional treatment modalities include fixed or removable prosthetic therapy, which may lead to many complications such as continuous alveolar bone resorption. ⁴The concept of osseointegration was introduced in the 1950s by Per-Ingvar Branemark. Nowadays, endosseous implants are a commonly accepted treatment option. However, osseointegration represents a direct connection between the implant and bone tissue and lacks the periodontium tissue present in natural teeth, which is regarded as an elastic isotropic material and modulate the mechanical stress of mastication. ⁵Therefore, the need for alternative tooth replacement therapies is quite evident.

Conventional root canal treatment of a necrotic pulp is not a sufficient management. Some endodontic filling materials and sealers or medicaments have the potential to discolor the tooth crown or weaken the tooth. ⁶Furthermore, dental pulp contains proprioceptors and therefore provides important sensory feedback on masticatory forces, a function that may reduce the potential for tooth fracture. ⁷

The creation and delivery of new tissues to be a substitute for diseased or traumatized pulp or missing teeth is referred to as regenerative therapies. The success of regenerative endodontic therapy is the ability to constitute a technique that will allow clinicians to create a functional pulp tissue. The source of pulp tissue may come from stem cell therapy, which involves the delivery of autologous stem cells into root canals; dental pulp constructs, which involves the surgical implantation of synthetic pulp tissue grow in the laboratory; or root canal revascularization. ⁸A clinical limitation to a blood clot revascularization approach is that concentration and composition of cells trapped in the fibrin clot are unpredictable that may lead to variations in treatment outcome. ⁹

Stem cells are considered the most valuable cells for regenerative medicine. Stem cells can be classified as either embryonic or postnatal stem cells. Both can contribute to the development of regenerative medicine. The immunological and ethical concerns due to allogenic embryonic stem cells may be overwhelmed by the use of postnatal stem cells. ¹⁰Furthermore, there have been many advances in postnatal stem cell research. Newer studies suggest that adult stem cells may have much greater plasticity than previously thought. There are various sources of stem cells in adult tissues, such as bone marrow, blood, brain, the eye, skeletal muscle, liver, dental pulp, skin, the lining of the gastrointestinal tract, and pancreas. ¹¹, ¹², ¹³Adult stem cells are rare, difficult to identify, purify, and culture. They can be classified as hematopoietic or mesenchymal stem cells. Bone marrow - derived mesenchymal stem cells have been the most studied mesenchymal stem cells. ¹⁴However, it is unclear if these cells have the capacity for dentinogenic differentiation. ¹⁵

Gronthos et al. were the first to isolate dental pulp stem cells (DPSCs) in 2000. ¹⁵Further investigations revealed that these cells have intensive capacity of differentiation into neuron-like cells, adipocytic, osteocytic, and chondrocytic cells. ¹⁶, ¹⁷, ¹⁸Moreover, DPSCs demonstrated a higher developmental potential and longer life span than bone marrow stromal stem cells. This has been found that the number of proliferating cells as well as the frequency of colony-forming cells was significantly higher in DPSCs when compared to bone marrow stromal stem cells too. ¹⁹On the other hand, DPSCs can be cryopreserved and used for regenerative purposes later. ²⁰Based upon these findings, dental pulp stem cells may be considered appropriate cell types for developing tissue engineering strategies and finding ways to culture them outside the body with high efficiency is a great priority of stem cell research.

Unfortunately, the stem cell population in the pulp is very small; approximately 1% of the total cells and the effect of aging reduce the cell pool available. ²¹As an important issue concerning the therapeutic use of stem cells is the quantity of cells necessary in order to achieve the best effect, harvesting and expanding the stem cells in culture are indispensable steps for regenerative medicine. ²²Hence, the goal of the present study was to design a modified dental pulp stem cell isolation method with high in vitro expansion potential and optimize the culture conditions for their increased proliferation.

Materials and Methods

0Sampling

Sixty impacted third molars used in this study were surgically removed from 45 healthy patients (18-30 years of age) by an oral surgeon. Informed consent was obtained from the patients after receiving approval by the Institutional Ethics Committee of Kerman University of Medical Sciences (Code: K/88/220). Before extraction, each subject was screened for systemic diseases by a health history and oral questioning. After a rinse with 0.2% chlorhexidine for 60 s a topical anesthetic gel was applied and teeth were anesthetized using lidocaine 2% with epinephrine 1/80 000 (Daroupakhsh, Tehran, Iran). Teeth that were cut during surgery or presenting a localized infection in the region were excluded from the study.

Isolation and culture of stem cells from dental pulp

The teeth were immersed in sterile phosphate buffer saline (PBS), stored on ice pack and immediately transported to the cell culture lab for sample processing. After cleaning the surface and disinfection with iodine, a horizontal groove was cut along the cementum-enamel junction using diamond fissure bur (DandZ., Wiesbaden, Germany) with high speed handpiece and copious water supply mounted on a high-speed hand piece to split the teeth and obtain the pulp tissue under sterile condition. All pulp tissues were minced into approximately 1.5 × 2 × 1 mm fragments. The teeth were randomly divided into three groups. Out of 60 samples, 20 were included in group I (digestion of pulp pieces by collagenase/dispase enzyme (Roche, Germany) and culture of the released cells following centrifugation); 20 in group II (outgrowth of the cells by culture of undigested pulp pieces) and the remaining 20 samples were in group III (digestion of pulp pieces and fixing them under a cover slip in the medium). In groups I and III, the fragments were digested in a solution of 1 mg/ml collagenase/dispase for 30 min at 37°C and centrifuged at 500 g for 5 min. Cell suspensions were seeded in 60 mm culture dishes containing minimum essential medium alpha modification (α-MEM); with 20% fetal bovine serum (FBS), 100 U/ml penicillin-G, 100 μg/ml streptomycin, and 1 μg/ml amphotrypsin B. ¹⁵Groups II and III received a coverslip to fix the tissue and prevent it from movement in the medium. All specimens were incubated at 37°C and 5% CO ₂in the incubator. The medium was changed every 3 days. The cells were passaged 1:5 with 0.25% trypsin/1 mM EDTA every 5 days. The cells were counted and their viability was determined by Ttrypan Blue staining. Cells were cryopreserved in a freezing medium composed of 65% α-MEM medium, 30% FBS, and 5% DMSO and vials were stored in liquid nitrogen tank until used. ¹⁵The student t-test was used for comparing the mean values of three independent groups. P value <0.05 was considered significant.

Mycoplasma detection

The cells were cultured on cover slips, fixed with methanol-acetone and stained with Hoechst 33558 (sigma) as recommended by the company and observed under fluorescent microscope (Axioplan 2, Zeiss) to reveal any contaminant mycoplasma. Images were captured with a digital camera (Powershot A260, Canon).

Extraction of Total RNA and cDNA synthesis

RNA-Easy Kit (Qiagen, Germany), according to manufacturer′s protocol was used. RNA measuring 0.5 μg was treated with RNase-free DNase I (Fermentas, Litany) to remove residual contamination with genomic DNA. Total DNA mixed with 0.2 μg of random hexamer and heated at 70°C for 5 min. The mixture was immediately chilled on ice for 5 min followed by the addition of 6.5 μl of a reverse transcription mixture prepared in a total volume of 19 μl containing 4 μl of 5× reaction buffer, 2 μl of 10mM dNTP, 0.5 μl RNase inhibitor. The mixture was incubated at 25°C for 5 min and then 1 μl M-ML V RT was added. The cDNA-synthesis reaction was performed at 42°C for 60 min.

Polymerase chain reaction and electrophoresis

Subsequent polymerase chain reaction (PCR) was as follows: 1 μl CDNA, 1.5 mM MgCl2, 200 μM dNTP, 0.4 μm of each specific primers and 1.25 unit/25 μl reaction Taq DNA polymerase (Cinnagen, Iran). Amplification was undertaken by initial at 94°C for 5 min, denaturation at 94°C for 30 s, annealing at 55°C for 30 s, extension at 72°C for 30 s and final extension at 72°C for 5 min. Each experiment was repeated three times. Specific primer pairs Table 1were designed by the primer 3 program written by the Whitehead Institute and oligonucleotides were synthesized by Isogen.{Table 1}

PCR products were size-fractionated on a 1.5% agarose gel and visualized by ethidium-bromide straining. The intensities of the PCR products were analyzed by Gene Tools software (Syngene, Cambridge, UK). Each experiment was repeated at least for three samples to obtain reproducible data.

Results

Cell growth and proliferation on culture dishes

The results demonstrated morphological differences in different groups. In group I a few cell colonies were found within 4 days after initial plating. Cells were homogenous fibroblast like in morphology Figure 1a. Figure 1

Digestion of pulp segments with collagenase/dispase destroys pulp scaffold, the spindle like cells are observed 2-3 days after primary culture (Figure a, 100X). Undigested pulp segments show an intact edge (Figure b, 100X) and yield cell later than digested tissue

Figure 1

In the outgrowth method 10-12 days were needed to allow sufficient numbers of cells. Cell migration through peripheral was also noticeable in this group Figure 1b. Colonies were heterogeneous in appearance with a barrel-shaped spindle and round configuration. Cells isolated by this method had the slowest proliferation rate.

Surprisingly, with the improved third method, only 1 or 2 days after the passage, heterogeneous fast growing populations of stem cells appeared. In this considerably high efficacy group, all the specimens exhibited increased rate of stem cell growth. The result demonstrated that the third method was more efficient (more than 60%) and the second method was less efficient (about 10%) in stem cell isolation and this differences were statistically significant (P < 0.05). To check the cells for mycoplasma contamination we used Hoechst staining solution. Fluorescence microscopy revealed that the nucleus of the stem cells appeared as a blue ellips, which demonstrated that the cells were not contaminated.

Gene expression patterns

We sought to examine the expression of Nucleostemin, Oct-4, jmj2c and Nanog as proliferation and self-renewal regulatory factors for stem cells. Based on the RT-PCR and agarose gel electrophoresis, the cells from all groups expressed all the genes Figure 2. Figure 2

Expression of stem cell markers Nucleostemin, Jmjd2c, Nanog and Oct-4, in the stem cells derived from human adult dental pulp

Figure 2

Discussion

The third molar is the last tooth to develop; it is normally in an early stage of development. Studies have shown that extracted nondecayed impacted third molars are capable of producing an optimum quantity of dental pulp tissue for the isolation of DPSCs. ²³, ²⁴Another positive point is that harvesting stem cells from this unavailing tissue after extraction causes no ethical controversy.

It is not possible to identify stem cells definitely in any tissue. Some indirect properties such as surface proteins, rapid cell cycle, clonogenicity, or an undifferentiated state offer significant implications for accuracy of diagnosis. ²⁵In this study, the expression of some genes including Nucleostemin, Oct-4, and Nanog, which are implicated in the proliferation and self-renewal of stem cells, was studied by RT-PCR assay.

Nucleostemin is a nucleolar protein cloned and described by Tsai and McKay. ²⁶It is described as a P53 binding protein in the nucleoli of cancer cells, neural and embryogenic stem cells and placenta tissue, but not in terminally differentiated cells. It is thought to be involved in regulation of self-renewal and cell cycle. ²⁶, ²⁷However, an increase of nucleostemin expression by RT-PCR could simply be the result of the proliferation of nucleostemin-positive cells, and not the result of promoting nucleostemin expression within each cell. ²⁸However, the expression of nucleostemin is reported as strong signals from the nucleoli, which is much more specific compared to p63, and therefore, may be superior as a progenitor marker. ²⁸

Nanog is a 305 amino acid protein with a conserved homeodomain belonging to the homeobox gene family. It was first described as a key transcription regulator defining human embryonic stem cell identity and self-renewal by both activating repressors of and suppressing activators of differentiation. ²⁹Down-regulation of Nanog induces differentiation, ³⁰and over-expression of Nanog induces pluripotency, ³¹as shown by the capacity for multi-lineage differentiation and perpetual self-renewal of cells expressing this gene.

Oct-4 is a transcription factor that is coded for by the Pou5f1v gene. The Oct-4 gene influences several genes expressed during early embryonic development, and thus may play a vital role in the processes of development and cell differentiation. ³²Maintaining Oct-4 expression within a certain range is required for stem cell renewal. However, increased Oct-4 expression provokes differentiation to endoderm or mesoderm and decreased Oct-4 expression is related to dedifferentiation to trophectoderm. ³³

As a whole, the expression of these genes in the isolated dental pulp cells indicates a potential role for them in controlling proliferation, survival, and self-renewal. Due to the expression of nucleostemin, Oct-4 and Nanog in the cells from all groups, our results suggest that there exists a population of stem cells in the pulp. This finding is in line with many previous reports, and it implies that the cells isolated from dental pulp are bona fide stem cell. ¹⁵, ²³, ²⁴, ³⁴

An important issue relevant to the therapeutic use of stem cells is the quantity of cells essential to attain an optimal effect. Expanding stem cells in culture is a crucial step for regenerative medicine, and a considerable attempt has been made to assess the consequences of the cultivation on stem cell behavior. ²²

Two methods usually have been employed to culture dental pulp stem cells. The first is the enzyme digestion method and the second one is the explant outgrowth method. Due to the decreased cell viability related to the enzyme treatment method, the explant outgrowth one has been suggested as the method of choice. ³⁵In this experiment, the isolation method had a bright effect on population expansion and our improved third method provided the greatest in vitro expansion than the two mentioned methods and may provide the most cells for biotechnological and biomedical applications. Huang et al. compared the enzyme digestion and outgrowth methods and found that cells isolated by enzyme digestion had a higher proliferation rate than those isolated by the other one. ³⁵Although our result is similar to Huang et al. study, it seems that the cells isolated by our improved method were less damaged and were therefore healthy enough to propagate longer in vitro than the other methods. Perhaps the other methods damage the cells or alternatively removed critical elements from the endogenous niche.

With our improved method, only 1 to 2 days after the primary culture, heterogeneous fast growing populations of stem cells appeared. There are different types of cells in the pulp. Odontoblasts, whose biological function is dentinogenesis, is part of the outer surface of the dental pulp. Capillaries and small nerve fibers ramify in the subodontoblastic layer. The cell-rich zone contains fibroblasts and undifferentiated cells. Central pulp zone includes the large vessels and nerves. Most of the cells of the pulp are fibroblasts. These cells exhibit wide variation in their degree of differentiation. ³⁶, ³⁷Perhaps multiple stem cells are capable of forming all these cells. We hypothesize that possibly, there exists more than one type of stem cells in the pulp and different methods of isolation could result in different cell types.

Conclusion

In conclusion, the results of the current study indicates that adult dental pulp contain stem cells that can be isolated and expanded efficiently. These cells are probably one of the sources of regeneration after pulp injury. They could be valuable in cell based therapeutic approaches too.

We suggest that further work in this area may provide an increased understanding of what is happening to these cells at harvest and over time in culture. This information is important in developing cell isolation procedures that produce the best chance for establishing the DPSC cells in vitro for later use in experiments and for biotechnology or cell therapies.

The authors would especially like to thank Dr. Babak Mohammadi at the Department of Oral and Maxillofacial Surgery for his tireless effort in providing the samples. This research would not have been possible without the financial support of the Research Committee of Kerman University of Medical Sciences.

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