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Abstract

Low back pain related to intervertebral disk (IVD) degeneration has a major socioeconomic impact on our aging society. Therefore, stem cell therapy to activate self-repair of the IVD remains an exciting treatment strategy. In this respect, tissue-specific progenitors may play a crucial role in IVD regeneration, as these cells are perfectly adapted to this niche. Such a rare progenitor cell population residing in the nucleus pulposus (NP) (NP progenitor cells [NPPCs]) was found positive for the angiopoietin-1 receptor (Tie2+), and was demonstrated to possess self-renewal capacity and in vitro multipotency. Here, we compared three sorting protocols; that is, fluorescence-activated cell sorting (FACS), magnetic-activated cell sorting (MACS), and a mesh-based label-free cell sorting system (pluriSelect), with respect to cell yield, potential to form colonies (colony-forming units), and in vitro functional differentiation assays for tripotency. The aim of this study was to demonstrate the efficiency of three widespread cell sorting methods for picking rare cells (<5%) and how these isolated cells then behave in downstream functional differentiation in adipogenesis, osteogenesis, and chondrogenesis. The cell yields among the isolation methods differed widely, with FACS presenting the highest yield (5.0% ± 4.0%), followed by MACS (1.6% ± 2.9%) and pluriSelect (1.1% ± 1.0%). The number of colonies formed was not significantly different between Tie2+ and Tie2− NPPCs. Only FACS was able to separate into two functionally different populations that showed trilineage multipotency, while MACS and pluriSelect failed to maintain a clear separation between Tie2+ and Tie2− populations in differentiation assays. To conclude, the isolation of NPPCs was possible with all three sorting methods, while FACS was the preferred technique for separation of functional Tie2+ cells.

Impact Statement

Tissue-specific progenitor cells such as nucleus pulposus progenitor cells of the IVD could become an ultimate cell source for tissue engineering strategies as these cells are presumably best adapted to the tissue's microenvironment. Fluorescence-activated cell sorting seemed to outcompete magnetic-activated cell sorting and pluriSelect concerning selecting a rare cell population from IVD tissue as could be demonstrated by improved cell yield and functional differentiation assays.

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References

Vos

, Flaxman

A.D.

, Naghavi

, et al. Years lived with disability (YLDs) for 1160 sequelae of 289 diseases and injuries 1990–2010: a systematic analysis for the Global Burden of Disease Study 2010. Lancet, 380, 2163, 2012.

Dagenais

, Caro

, and Haldeman

A systematic review of low back pain cost of illness studies in the United States and internationally. Spine J, 8, 8, 2008.

Balagué

, Mannion

A.F.

, Pellisé

, and Cedraschi

Non-specific low back pain. Lancet, 379, 482, 2012.

Schizas

, Kulik

, and Kosmopoulos

Disc degeneration: current surgical options. Eur Cell Mater, 20, 306, 2010.

Schol

, and Sakai

Cell therapy for intervertebral disc herniation and degenerative disc disease: clinical trials. Int Orthop, 43, 1011, 2018.

Benneker

L.M.

, Andersson

, Iatridis

J.C.

, et al. Cell therapy for intervertebral disc repair: advancing cell therapy from bench to clinics. Eur Cell Mater, 27, 5, 2014.

Vedicherla

, and Buckley

C.T.

Cell-based therapies for intervertebral disc and cartilage regeneration—current concepts, parallels, and perspectives. J Orthop Res, 35, 8, 2017.

Sakai

, and Schol

Cell therapy for intervertebral disc repair: clinical perspective. J Orthop Translat, 9, 8, 2017.

Huang

Y.C.

, Urban

J.P.

, and Luk

K.D.

Intervertebral disc regeneration: do nutrients lead the way? Nat Rev Rheumatol, 10, 561, 2014.

10.

Thorpe

A.A.

, Bach

F.C.

, Tryfonidou

M.A.

, et al. Leaping the hurdles in developing regenerative treatments for the intervertebral disc from preclinical to clinical. JOR Spine, 1, e1027, 2018.

11.

Squillaro

, Peluso

, and Galderisi

Clinical trials with mesenchymal stem cells: an update. Cell Transplant, 25, 829, 2016.

12.

Vadalà

, Russo

, Ambrosio

, et al. Stem cells sources for intervertebral disc regeneration. World J Stem Cells, 8, 185, 2016.

13.

Yim

R.L.

, Lee

J.T.

, Bow

C.H.

, et al. A systematic review of the safety and efficacy of mesenchymal stem cells for disc degeneration: insights and future directions for regenerative therapeutics. Stem Cells Dev, 23, 2553, 2014.

14.

Maroudas

, Stockwell

R.A.

, Nachemson

, and Urban

Factors involved in the nutrition of the human lumbar intervertebral disc: cellularity and diffusion of glucose in vitro. J Anat, 120, 113, 1975.

15.

Miyazaki

, Kobayashi

, Takeno

, et al. A phenotypic comparison of proteoglycan production of intervertebral disc cells isolated from rats, rabbits, and bovine tails; which animal model is most suitable to study tissue engineering and biological repair of human disc disorders? Tissue Eng Part A, 15, 3835, 2009.

16.

Sakai

, Nakamura

, Nakai

, et al. Exhaustion of nucleus pulposus progenitor cells with ageing and degeneration of the intervertebral disc. Nat Commun, 3, 1264, 2012.

17.

Tekari

, Chan

S.C.

, Sakai

, et al. Angiopoietin-1 receptor Tie2 distinguishes multipotent differentiation capability in bovine coccygeal nucleus pulposus cells. Stem Cell Res Ther, 7, 75, 2016.

18.

Sakai

, Schol

, Bach

F.C.

, et al. Successful fishing for nucleus pulposus progenitor cells of the intervertebral disc across species. JOR Spine, 2018, e1018, 2018.

19.

Rodrigues-Pinto

, Ward

, Humphreys

, et al. Human notochordal cell transcriptome unveils potential regulators of cell function in the developing intervertebral disc. Sci Rep, 8, 12866, 2018.

20.

, Zeng

, Yu

, et al. Comparison of nucleus pulposus stem/progenitor cells isolated from degenerated intervertebral discs with umbilical cord derived mesenchymal stem cells. Exp Cell Res, 361, 324, 2017.

21.

Lyu

F.J.

, Cheung

K.M.

, Zheng

, et al. IVD progenitor cells: a new horizon for understanding disc homeostasis and repair. Nat Rev Rheumatol, 15, 102, 2019.

22.

Henriksson

, Thornemo

, Karlsson

, et al. Identification of cell proliferation zones, progenitor cells and a potential stem cell niche in the intervertebral disc region: a study in four species. Spine (Phila Pa 1976), 34, 2278, 2009.

23.

Liu

L.T.

, Huang

, Li

C.Q.

, et al. Characteristics of stem cells derived from the degenerated human intervertebral disc cartilage endplate. PLoS One, 6, e26285, 2011.

24.

X.-C.

, Bai

X.-D.

, Xin

H.-K.

, et al. Cell properties of nucleus pulposus progenitor cells declines with intervertebral disc degeneration. Oncotarget, 5, 13, 2017.

25.

Pfirrmann

C.W.

, Metzdorf

, Zanetti

, et al. Magnetic resonance classification of lumbar intervertebral disc degeneration. Spine (Phila Pa 1976), 26, 1873, 2001.

26.

Chan

S.C.

, and Gantenbein-Ritter

Preparation of intact bovine tail intervertebral discs for organ culture. J Vis Exp, 60, e3490, 2012.

27.

Dennis

J.E.

, Carbillet

J.P.

, Caplan

A.I.

, and Charbord

The STRO-1+ marrow cell population is multipotential. Cells Tissues Organs, 170, 73, 2002.

28.

Halleux

, Sottile

, Gasser

J.A.

, and Seuwen

Multi-lineage potential of human mesenchymal stem cells following clonal expansion. J Musculoskelet Neuronal Interact, 2, 71, 2001.

29.

Mackay

A.M.

, Beck

S.C.

, Murphy

J.M.

, et al. Chondrogenic differentiation of cultured human mesenchymal stem cells from marrow. Tissue Eng, 4, 415, 1998.

30.

Mauck

R.L.

, Yuan

, and Tuan

R.S.

Chondrogenic differentiation and functional maturation of bovine mesenchymal stem cells in long-term agarose culture. Osteoarthritis Cartilage, 14, 179, 2006.

31.

Agar

, Blumenstein

, Bar-Ziv

, et al. The chondrogenic potential of mesenchymal cells and chondrocytes from osteoarthritic subjects: a comparative analysis. Cartilage, 2, 40, 2011.

32.

Plouffe

B.D.

, Murthy

S.K.

, and Lewis

L.H.

Fundamentals and application of magnetic particles in cell isolation and enrichment: a review. Rep Prog Phys, 78, 016601, 2015.

33.

Lotz

, Goderie

, Tokas

, et al. Sustained levels of FGF2 maintain undifferentiated stem cell cultures with biweekly feeding. PLoS One, 8, e56289, 2013.

34.

Tang

, Jing

, Willard

V.P.

, et al. Differentiation of human induced pluripotent stem cells into nucleus pulposus-like cells. Stem Cell Res Ther, 9, 61, 2018.

35.

Teichert

, Milde

, Holm

, et al. Pericyte-expressed Tie2 controls angiogenesis and vessel maturation. Nat Commun, 8, 16106, 2017.

36.

Serigano

, Sakai

, Hiyama

, et al. Effect of cell number on mesenchymal stem cell transplantation in a canine disc degeneration model. J Orthop Res, 28, 1267, 2010.

37.

Hiraishi

, Schol

, Sakai

, et al. Discogenic cell transplantation directly from a cryopreserved state in an induced intervertebral disc degeneration canine model. JOR Spine, 1, e1013, 2018.

38.

Pettine

K.A.

, Murphy

M.B.

, Suzuki

R.K.

, and Sand

T.T.

Percutaneous injection of autologous bone marrow concentrate cells significantly reduces lumbar discogenic pain through 12 months. Stem Cells, 33, 146, 2015.

39.

Orozco

, Soler

, Morera

, et al. Intervertebral disc repair by autologous mesenchymal bone marrow cells: a pilot study. Transplantation, 92, 822, 2011.

40.

Ménard

, and Tarte

Immunoregulatory properties of clinical grade mesenchymal stromal cells: evidence, uncertainties, and clinical application. Stem Cell Res Ther, 4, 64, 2013.

41.

Shields

C.W.

, Reyes

C.D.

, and López

G.P.

Microfluidic cell sorting: a review of the advances in the separation of cells from debulking to rare cell isolation. Lab Chip, 15, 1230, 2015.

42.

Tang

, Jiang

, Li

, et al. Recent advances in microfluidic cell sorting techniques based on both physical and biochemical principles. Electrophoresis, 40, 930, 2018.

43.

Moritz

, Schniering

, Distler

J.H.W.

, et al. Tie2 as a novel key factor of microangiopathy in systemic sclerosis. Arthritis Res Ther, 19, 105, 2017.

44.

Parikh

S.M.

The Angiopoietin-Tie2 signaling axis in systemic inflammation. J Am Soc Nephrol, 28, 1973, 2017.

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Fluorescence-Activated Cell Sorting Is More Potent to Fish Intervertebral Disk Progenitor Cells Than Magnetic and Beads-Based Methods

Abstract

Impact Statement

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Supplementary Material