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Abstract

Preterm white matter injury (WMI) is an important cause for long-term disability. Stem cell transplantation has been proposed as a novel therapeutic approach. However, intracerebral transplantation is not feasible for clinical purpose in newborns. Intranasal delivery of cells to the brain might be a promising, noninvasive therapeutic approach to restore the damaged brain. Therefore, our goal is to study the remyelinating potential of human Wharton's jelly mesenchymal stem cells (hWJ-MSCs) after intranasal delivery. Wistar rat pups, previously brain-damaged by a combined hypoxic-ischemic and inflammatory insult, received hWJ-MSC (150,000 cells in 3 μL) that were intranasally delivered twice to each nostril (600,000 cells total). WMI was assessed by immunohistochemistry and western blot for myelination, astrogliosis, and microgliosis. The expression of preoligodendrocyte markers, and neurotrophic factors, was analyzed by real-time polymerase chain reaction. Animals treated with intranasally delivered hWJ-MSC showed increased myelination and decreased gliosis compared to untreated animals. hWJ-MSC may, therefore, modulate the activation of microglia and astrocytes, resulting in a change of the brain microenvironment, which facilitates the maturation of oligodendrocyte lineage cells. This is the first study to show that intranasal delivery of hWJ-MSC in rats prevented hypomyelination and microgliosis in a model of WMI in the premature rat brain. Further studies should address the dose and frequency of administration.

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References

Blumenthal

. (2004). Periventricular leucomalacia: a review. Eur J Pediatr, 163:435–442.

Hagberg

, Mallard

, Ferriero

, Vannucci

, Levison

, Vexler

and Gressens

. (2015). The role of inflammation in perinatal brain injury. Nat Rev Neurol, 11:192–208.

Borghesi

, Cova

, Gazzolo

and Stronati

. (2013). Stem cell therapy for neonatal diseases associated with preterm birth. J Clin Neonatol, 2:1–7.

Back

. (2015). Brain injury in the preterm infant: new horizons for pathogenesis and prevention. Pediatr Neurol, 53:185–192.

Bonestroo

, Heijnen

, Groenendaal

, van Bel

and Nijboer

. (2015). Development of cerebral gray and white matter injury and cerebral inflammation over time after inflammatory perinatal asphyxia. Dev Neurosci, 37:78–94.

Grether

and Nelson

. (1997). Maternal infection and cerebral palsy in infants of normal birth weight. JAMA, 278:207–211.

Segovia

, McClure

, Moravec

, Luo

, Wan

, Gong

, Riddle

, Craig

, Struve

, Sherman

and Back

. (2008). Arrested oligodendrocyte lineage maturation in chronic perinatal white matter injury. Ann Neurol, 63:520–530.

Taghizadeh

, Cetrulo

and Cetrulo

. (2011). Wharton's Jelly stem cells: future clinical applications. Placenta, 32 (Suppl 4):S311–S315.

Watson

, Divers

, Kedar

, Mehindru

, Borlongan

and Borlongan

. (2015). Discarded Wharton jelly of the human umbilical cord: a viable source for mesenchymal stromal cells. Cytotherapy, 17:18–24.

10.

Carroll

and Borlongan

. (2008). Adult stem cell therapy for acute brain injury in children. CNS Neurol Disord Drug Targets, 7:361–369.

11.

Sizonenko

, Sirimanne

, Mayall

, Gluckman

, Inder

and Williams

. (2003). Selective cortical alteration after hypoxic-ischemic injury in the very immature rat brain. Pediatr Res, 54:263–269.

12.

Stadlin

, James

, Fiscus

, Wong

, Rogers

and Haines

. (2003). Development of a postnatal 3-day-old rat model of mild hypoxic-ischemic brain injury. Brain Res, 993:101–110.

13.

Craig

, Ling Luo

, Beardsley

, Wingate-Pearse

, Walker

, Hohimer

and Back

. (2003). Quantitative analysis of perinatal rodent oligodendrocyte lineage progression and its correlation with human. Exp Neurol, 181:231–240.

14.

Messerli

, Wagner

, Sager

, Mueller

, Baumann

, Surbek

and Schoeberlein

. (2013). Stem cells from umbilical cord Wharton's jelly from preterm birth have neuroglial differentiation potential. Reprod Sci, 20:1455–1464.

15.

Donega

, van Velthoven

, Nijboer

, van Bel

, Kas

, Kavelaars

and Heijnen

. (2013). Intranasal mesenchymal stem cell treatment for neonatal brain damage: long-term cognitive and sensorimotor improvement. PLoS One, 8:e51253.

16.

Liu

, Silverstein

, Skoff

and Barks

. (2002). Hypoxic-ischemic oligodendroglial injury in neonatal rat brain. Pediatr Res, 51:25–33.

17.

Zaidi

, Bessert

, Ong

, Xu

, Barks

, Silverstein

and Skoff

. (2004). New oligodendrocytes are generated after neonatal hypoxic-ischemic brain injury in rodents. Glia, 46:380–390.

18.

Mifsud

, Zammit

, Muscat

, Di Giovanni

and Valentino

. (2014). Oligodendrocyte pathophysiology and treatment strategies in cerebral ischemia. CNS Neurosci Ther, 20:603–612.

19.

Back

, Han

, Luo

, Chricton

, Xanthoudakis

, Tam

, Arvin

and Holtzman

. (2002). Selective vulnerability of late oligodendrocyte progenitors to hypoxia-ischemia. J Neurosci, 22:455–463.

20.

Salgado

, Sousa

, Costa

, Pires

, Mateus-Pinheiro

, Teixeira

, Pinto

and Sousa

. (2015). Mesenchymal stem cells secretome as a modulator of the neurogenic niche: basic insights and therapeutic opportunities. Front Cell Neurosci, 9:249.

21.

Ramos-Cejudo

, Gutierrez-Fernandez

, Otero-Ortega

, Rodriguez-Frutos

, Fuentes

, Vallejo-Cremades

, Hernanz

, Cerdan

and Diez-Tejedor

. (2015). Brain-derived neurotrophic factor administration mediated oligodendrocyte differentiation and myelin formation in subcortical ischemic stroke. Stroke, 46:221–228.

22.

Razavi

, Nazem

, Mardani

, Esfandiari

, Salehi

and Esfahani

. (2015). Neurotrophic factors and their effects in the treatment of multiple sclerosis. Adv Biomed Res, 4:53.

23.

Madathil

and Saatman

. (2015). IGF-1/IGF-R Signaling in traumatic brain injury: impact on cell survival, neurogenesis, and behavioral outcome. In: Kobeissy

, ed. Brain Neurotrauma: Molecular, Neuropsychological, and Rehabilitation Aspects. Boca Raton, FL: CRC Press/Taylor & Francis; Chapter 7.

24.

, Fu

, Shan

, Shen

, Zhang

, Lei

and Jin

. (2009). MSCs guide neurite directional extension and promote oligodendrogenesis in NSCs. Biochem Biophys Res Commun, 384:372–377.

25.

Relucio

, Menezes

, Miyagoe-Suzuki

, Takeda

and Colognato

. (2012). Laminin regulates postnatal oligodendrocyte production by promoting oligodendrocyte progenitor survival in the subventricular zone. Glia, 60:1451–1467.

26.

Back

, Tuohy

, Chen

, Wallingford

, Craig

, Struve

, Luo

, Banine

, Liu

, et al. (2005). Hyaluronan accumulates in demyelinated lesions and inhibits oligodendrocyte progenitor maturation. Nat Med, 11:966–972.

27.

Preston

, Gong

, Su

, Matsumoto

, Banine

, Winkler

, Foster

, Xing

, Struve

, et al. (2013). Digestion products of the PH20 hyaluronidase inhibit remyelination. Ann Neurol, 73:266–280.

28.

Kota

, Prabhakara

, Cox

and Olson

. (2014). MSCs and hyaluronan: sticking together for new therapeutic potential?. Int J Biochem Cell Biol, 55:1–10.

29.

Jellema

, Wolfs

, Lima Passos

, Zwanenburg

, Ophelders

, Kuypers

, Hopman

, Dudink

, Steinbusch

, et al. (2013). Mesenchymal stem cells induce T-cell tolerance and protect the preterm brain after global hypoxia-ischemia. PLoS One, 8:e73031.

30.

Danielyan

, Schafer

, von Ameln-Mayerhofer

, Bernhard

, Verleysdonk

, Buadze

, Lourhmati

, Klopfer

, Schaumann

, et al. (2011). Therapeutic efficacy of intranasally delivered mesenchymal stem cells in a rat model of Parkinson disease. Rejuvenation Res, 14:3–16.

31.

Bruno

, Deregibus

and Camussi

. (2015). The secretome of mesenchymal stromal cells: role of extracellular vesicles in immunomodulation. Immunol Lett, 168:154–158.

32.

Charlton

, Jones

, Davis

and Illum

. (2007). Distribution and clearance of bioadhesive formulations from the olfactory region in man: effect of polymer type and nasal delivery device. Eur J Pharm Sci, 30:295–302.

33.

Soane

, Frier

, Perkins

, Jones

, Davis

and Illum

. (1999). Evaluation of the clearance characteristics of bioadhesive systems in humans. Int J Pharm, 178:55–65.

34.

Dhuria

, Hanson

and Frey

2nd. (2009). Novel vasoconstrictor formulation to enhance intranasal targeting of neuropeptide therapeutics to the central nervous system. J Pharmacol Exp Ther, 328:312–320.

35.

Gross

, Swenberg

, Fields

and Popp

. (1982). Comparative morphometry of the nasal cavity in rats and mice. J Anat, 135:83–88.

36.

Jiang

, Zhu

, Xu

and Liu

. (2011). Intranasal delivery of stem cells to the brain. Expert Opin Drug Deliv, 8:623–632.

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Intranasal Delivery of Umbilical Cord-Derived Mesenchymal Stem Cells Preserves Myelination in Perinatal Brain Damage

Abstract

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