Scratch-Based Isolation of Primary Cells (SCIP): A Novel Method to Obtain a Large Number of Human Dental Pulp Cells Through One-Step Cultivation

Overview

Journal J Clin Med

Specialty General Medicine

Date 2024 Dec 17

PMID 39685514

Authors

Yuki Kiyokawa

Masahiko Terajima

Masahiro Sato

Emi Inada

Yuria Hori

Ryo Bando

Yoko Iwase

Naoko Kubota

Tomoya Murakami

Hiroko Tsugane

Satoshi Watanabe

Takahiro Sonomura

Miho Terunuma

Takeyasu Maeda

Hirofumi Noguchi

Issei Saitoh

Affiliations

Soon will be listed here.

Abstract

Dental pulp (DP) is a connective tissue composed of various cell types, including fibroblasts, neurons, adipocytes, endothelial cells, and odontoblasts. It contains a rich supply of pluripotent stem cells, making it an important resource for cell-based regenerative medicine. However, current stem cell collection methods rely heavily on the enzymatic digestion of dissected DP tissue to isolate and propagate primary cells, which often results in low recovery rates and reduced cell survival, particularly from deciduous teeth. We developed a novel and efficient method to obtain a sufficient number of cells through a one-step cultivation process of isolated DP. After the brief digestion of DP with proteolytic enzymes, it was scratched onto a culture dish and cultured in a suitable medium. By day 2, the cells began to spread radially from DP, and by day 10, they reached a semi-confluent state. Cells harvested through trypsinization consistently yielded over 1 million cells, and after re-cultivation, the cells could be propagated for more than ten passages. The proliferative and differentiation capacities of the cells after the 10th passage were comparable to those from the first passage. The cells expressed alkaline phosphatase as an undifferentiation marker. Similarly, they also maintained the constitutive expression of stem cell-specific markers and differentiation-related markers, even after the 10th passage. This method, termed "scratch-based isolation of primary cells from human dental pulps (SCIP)", enables the efficient isolation of a large number of DP cells with minimal equipment and operator variability, while preserving cell integrity. Its simplicity, high success rate, and adaptability for patients with genetic diseases make it a valuable tool for regenerative medicine research and clinical applications.

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