Sage Journals: Discover world-class research

Abstract

Intravenous administration of human umbilical tissue-derived cells (hUTC) improves neurological function in young adult rats after stroke. However, stroke is a major cause of death and disability in the aged population, with the majority of stroke patients 65 years and older. The present study investigated the effect of hUTC on aged rats after embolic stroke. Rats at the age of 18–20 months were subjected to embolic middle cerebral artery (MCA) occlusion. Two groups of eight animals each were compared. The investigational group was injected intravenously with 1 × 10⁷ cells/kg in serum-free culture medium (vehicle) 24 h after stroke onset, and the control group was treated with vehicle only at the same time poststroke. Intravenous administration of hUTC significantly improved neurological functional recovery without reducing infarct volume compared to vehicle-treated aged rats. Additionally, hUTC treatment significantly enhanced synaptogenesis and vessel density in the ischemic boundary zone (IBZ). Moreover, hUTC treatment resulted in a trend toward increased progenitor cell proliferation in the subventricular zone (SVZ) compared to vehicle-treated aged rats. Intravenous administration of hUTC improved functional recovery in aged rats after stroke. The enhancement of synaptogenesis and vessel density may contribute to the beneficial effects of hUTC in the treatment of stroke in the aged animal.

Keywords

Cerebral infarct Human umbilical cord Synaptogenesis Stroke recovery Aged rat model

Introduction

According to the 2011 statistical update on heart diseases and stroke in the US, approximately 795,000 people experience a new or recurrent stroke each year (50). Stroke is the third leading cause of death and a major cause of long-term disability in the US. The only therapeutic intervention available for stroke is the use of thrombolytic drugs, the success of which is governed by the narrow time window in which they need to be administered. Therefore, alternative strategies for stroke treatment are necessary. Infusion of cell-based therapies represents a promising approach for neurorestoration after stroke. Human cells isolated from various sources such as the brain, bone marrow, cord blood, and adipose tissue have been utilized for neurorestoration after stroke. Human umbilical cord blood cells (hUCBCs) are an attractive source of cells for cell-based therapies because they can be collected without the ethical conflicts that are associated with embryonic or fetal cells. Further, they have been shown to have the ability to develop into nonhematopoietic cells of various tissue lineages, including neural cells (21). In addition to cord blood, the umbilical cord tissue itself is a particularly attractive source of cells, especially considering that the cells can be harvested non-invasively from tissue that is normally discarded without the ethical conflicts of other cell sources (9,16,18,35,53). In fact, human umbilical tissue-derived cells (hUTC) have demonstrated a remarkable ability to improve neurological functional recovery in a rodent model of cerebral ischemia (58). The beneficial effects of hUTC are likely attributed to their ability to evoke host brain restorative processes including neurogenesis and vascular and synaptic plasticity (58). Previously, the effects of cord blood cells and hUTC in experimental stroke models have been exclusively studied in young adult rats in the age range of 12–13 weeks (10,48,56,58). However, none of the studies have focused on the therapeutic efficacy of umbilical cord blood- or tissue-derived cells to treat stroke in aged rats. In order to study the efficacy of treatment regimens in an age-associated disorder like stroke, it is crucial to use an age-appropriate animal model, as it has been demonstrated that aged animals respond differently to experimentally induced stroke than younger animals. For example, it has been shown that histopathological changes (the infiltration of macrophages into cerebral infarcts and the hypertrophy of astroglial fibrils surrounding these infarcts) induced by cerebral infarction were significantly reduced in aged animals (23–24 months old) when compared with young adult rats (2–4 months old; average rat life span being 27–29 months) (20). Although the mechanisms by which infused hUCBCs induce functional benefit after stroke are not clear (10), reduced inflammation and nerve fiber reorganization have been proposed as possible mechanisms of neurorestoration after embolic stroke (3,13,34). Since aging is associated with changes in the immune system, efficacy studies of therapeutic agents that participate in altering immune/inflammatory responses after cerebral infarction in young rats may not necessarily be extrapolated to old animals (3).

While the adult brain has the capacity for plasticity and self-repair following brain injury, brain plasticity postinjury declines with age (11,15,51,52). Clinical studies indicate that advanced age is a significant prognostic factor for poor stroke recovery (29,30,43), and stroke rehabilitation is less effective in the aged population compared with younger patients (46). In experimental stroke, previous studies indicate that aging is associated with diminished neurogenesis, angiogenesis, and synaptic plasticity, one or all of which can impair brain functional recovery after stroke (6,7,25,42,44,49). Therefore, while hUTC were shown to enhance motor-sensory recovery in young adult rats (58), no evidence existed to determine whether this effect would also be observed in aged animals. In the present study, we tested the effects of hUTC on neurological functional recovery in aged rats (18–20 months of age) when administered intravenously at 24 h after stroke. Our embolic stroke model in old rats is particularly important in light of the fact that nearly 75% of all strokes occur in people older than 65 years (37). Moreover, age is the single most important risk factor in stroke, and for each successive 10 years after age 55, the stroke rate more than doubles in both men and women (37). In contrast to the abundant studies of cell-based therapies in young adult rats, there is a scarcity of literature in aged mice. Our study is the first to describe the effects of hUTC in the aged rat after stroke.

Materials and Methods

All experimental procedures were approved by the Institutional Animal Care and Use Committee of Henry Ford Hospital. All outcome measurements were assessed by observers blinded to the treatments.

Preparation of hUTC

Human umbilical tissue-derived cells (hUTC) were isolated from a single donor following informed consent and ethical approval as described elsewhere (35). Cell preparation for implantation was described elsewhere (58). Briefly, cells were prepared for injection immediately prior to delivery. Cell vials were thawed in a 37°C water bath, and then washed with vehicle, a serum-free proprietary formulation. Aliquots of the cell suspension were removed and mixed with trypan blue (Sigma, St. Louis, MO, USA), and cells were counted with a hemato cytometer. The cell concentration in the cell suspension was adjusted to the appropriate concentration with vehicle as determined by the animal weight (1 × 10⁷ cells/kg in 2 ml of vehicle). Vehicle-only samples were prepared for injection in control animals.

Experimental Protocol

Male Wistar rats of ages 18–20 months, weighing 450– 600 g (Charles River Breeding, France), are referred to as aged rats. All rats were subjected to embolic middle cerebral artery (MCA) occlusion (61). Briefly, rats were anesthetized with 3.5% isoflurane (Baxter, Deerfield, IL, USA) in N₂O/O₂ (2:1) and maintained at 1.5% isoflurane via a facemask. The right common carotid artery, external carotid artery, and internal carotid artery were exposed. A modified PE-50 catheter (BD, San Jose, CA, USA) with a 0.3-mm outer diameter filled with a single clot was gently advanced from the right external carotid artery (ECA) into the lumen of the internal carotid artery (ICA), near the origin of the MCA. The clot was then injected along with 2–3 μl of saline (61). To test the effect of hUTC in aged rats after stroke, hUTC at a dose of 1 × 10⁷ cells/kg (n = 8) were intravenously administered via the tail vein 24 h after stroke onset. The dose selected for the current study is based on our previous study, which demonstrated that intravenous administration of hUTC at a dose of 1 × 10⁷ cells/kg elicits neurorestorative responses in young rats after stroke (58). The same volume of vehicle only (2 ml) was administered to ischemic rats (n = 8) as a control group, at 24 h poststroke. For mitotic labeling of cell proliferation, bromodeoxyuridine (BrdU; Sigma) at a dose of 50 mg/kg was intraperitoneally administered to rats for 14 consecutive days, starting 24 h after stroke onset.

Functional Outcome

All functional outcome tests were performed weekly by observers blinded to the treatments, starting 1 day after onset of MCA occlusion.

Modified Neurological Severity Score (mNSS)

mNSS is a composite of motor, sensory, reflex, and balance tests (10). Neurological function was graded on a scale of 0 (normal) to 18 (maximal deficit).

Adhesive Removal Test

An adhesive removal test was applied to measure somatosensory function deficits after brain injury (54). Briefly, two pieces of adhesive-backed paper dots (113.1 mm²) were used as bilateral tactile stimuli occupying the distal-radial region on the wrist of each forelimb for the first 4 weeks after stroke onset. Thereafter, half-sized stimuli (56.6 mm²) were used to increase the difficulty of the adhesive removal test, starting 35 days poststroke. This method is sensitive in measuring long-term functional outcome after stroke (54). Each animal received three trials per testing day, and the mean time (seconds) required to remove stimuli was recorded.

Foot-Fault Test

Rats were tested for placement dysfunctions of forelimbs with the modified foot-fault test (23). The total number of steps (movement of each forelimb) that the rat used to cross the grid and the total number of foot-faults for the left forelimb were recorded. Data are presented as a percentage of left foot-faults.

Measurements of Infarct Volume

Rats were sacrificed 60 days after stroke. Infarct volume was measured on seven hematoxylin and eosin (H&E; Sigma)-stained coronal sections using a Global Lab Image analysis program (Data Translation, Marlboro, MA, USA), as previously described (61). The infarct volume is presented as a percentage of total contralateral hemisphere volume.

Immunohistochemistry

Immunohistochemical studies were performed on coronal sections corresponding to bregma −1.0 to 1.0 mm obtained from each experimental animal. To identify proliferating cells, monoclonal antibody (mAb) against BrdU (Dako, Carpinteria, CA, USA) was used at a titer of 1:100. For quantification, the number of BrdU-incorporating subventricular zone (SVZ) cells and the area of SVZ were measured. Data are presented as density of BrdU-immunoreactive cells within the SVZ.

To detect human cells, a mAb against human mitochondria (HM; Spring Bioscience, Pleasanton, CA, USA) was used at a titer of 1:100. The numbers of HM immunoreactive cells within the ipsilateral hemisphere were measured and presented as the density of HM-positive cells within the ipsilateral hemisphere. Double stainings were performed to visualize cellular colocalization of HM with the neuron-specific marker microtubule-associated protein (MAP2) (Aves, Tigard, OR, USA) at a dilution of 1:1,000, and with glial fibrillary acidic protein (GFAP; Dako), an astrocyte marker, at a dilution of 1:10,000.

For a morphological analysis of vessels, a polyclonal antibody against von Willebrand factor (vWF; Dako) was used at a titer of 1:400. The number of vWF-immunoreactive vessels in the ischemic boundary zone (IBZ) was measured, as previous described (58). The IBZ was defined as the morphological area surrounding the lesion cavity immediately adjacent to the nonischemic tissue with an approximately 500 μm wide frame. Data are presented as the density of vWF-immunoreactive vessels within the IBZ.

Synaptophysin is a glycoprotein found in presynaptic vesicles, which has been used as a marker for synaptic plasticity (36). To detect presynaptic plasticity and synaptogenesis, a mAb against synaptophysin (Chemicon, Billerica, MA, USA) was used at a titer of 1:500. The synaptophysin-immunoreactive area in the IBZ was measured. Data are presented as percentage of synaptophysin-immunoreactive areas within the IBZ.

Statistical Analyses

Behavioral data were evaluated for normality, and a nonparametric analysis was considered if data did not follow a normal distribution. An analysis of variance (ANOVA) was conducted to test the treatment effect on each outcome between groups at each time point, followed by the post hoc least significant difference tests. Histology data were evaluated using a Student t test. All data are presented as mean ± SE. A treatment effect was detected if p < 0.05.

Results

Mortality

The mortality rates were 33% (4 of 12) and 27% (3 of 11) for rats treated with hUTC and vehicle control, respectively. In addition, two animals died within 24 h after stroke onset prior to treatment. Autopsy revealed that these animals had massive ipsilateral hemispheric swelling and/or hemorrhage. No significant differences were detected among the groups. Rats that died were excluded from further evaluation. The total number of animals remaining in this study was eight per group.

Lesion Volume

Lesion volume was comparable between rats treated with hUTC (26.7 ± 7.3%) and vehicle (26.6 ± 9.4%).

Neurological Functional Outcome

All rats exhibited severe functional deficits 24 h after stroke onset and with no significant differences measured by mNSS, foot-fault test, and adhesive removal test among the groups. Administration of hUTC 24 h after MCA occlusion significantly (p < 0.05) improved neurological functional outcome as measured by the foot-fault test starting from day 35, and by the adhesive removal test starting from day 42, which persisted up to 60 days after stroke. In addition, rats treated with hUTC exhibited significant improvements in mNSS at day 60 after ischemia compared with the control group (Fig. 1).

Figure 1.

Neurological functional outcome. Graphs showing outcomes from foot-fault test (A), adhesive removal test (B), and modified neurological severity score (mNSS) (C). Tests were conducted 24 h poststroke and then weekly, up to 60 days after middle cerebral artery (MCA) occlusion. Values are means ± SE. hUTC, human umbilical tissue-derived cells. *p < 0.05.

Detection of Human Cells

Few HM immunoreactive cells (1.1 ± 0.9/mm²) were detected within the ipsilateral hemisphere of rats treated with hUTC. Double immunostaining revealed that HM-positive cells were not reactive for MAP2 or GFAP.

Effects of hUTC on SVZ Cell Proliferation

To examine whether administration of hUTC enhanced SVZ cell proliferation, BrdU-incorporating SVZ cells were measured at 60 days after stroke onset. Rats treated with hUTC exhibited a trend toward an increase in the density of BrdU-positive cells in the ipsilateral SVZ compared with the vehicle-treated rats (p = 0.07). However, the density of BrdU-positive cells in the contralateral SVZ was not significantly affected by the administration of hUTC (Fig. 2).

Figure 2.

BrdU-positive cells in the SVZ. Representative micrographs of bromodeoxyuridine (BrdU) immunoreactivity in rats treated with vehicle (A, B) and hUTC (C, D) acquired from the ipsilateral (A, C) and contralateral (B, D) subventricular zone (SVZ) at 60 days post-MCA occlusion. Quantitative data (E) showing the density (number of cells/mm²) of BrdU-positive cells in the ipsilateral and contralateral SVZ. LV, lateral ventricle. *p < 0.05. Scale bar: 50 μm.

Effects of hUTC on Synaptophysin

Animals treated with hUTC exhibited significantly (p < 0.05) higher synaptophysin expression in the IBZ compared to rats treated with vehicle 60 days after stroke onset (Fig. 3).

Figure 3.

Synaptophysin immunoreactivity in the IBZ. Representative micrographs of synaptophysin immunoreactivity in rats treated with vehicle (A, B) and hUTC (C, D) at 60 days after MCA occlusion. (B) and (D) are high-magnification images from the boxed areas in (A) and (C), respectively. (E) Quantitative data showing the percentage of synaptophysin-immunoreactive area in the ischemic boundary zone (IBZ). *p < 0.05. Scale bar: 500 μm.

Effects of hUTC on Vascular Density

Animals treated with hUTC showed significantly (p < 0.05) higher density of vWF-immunoreactive vessels in the IBZ compared with vehicle-treated rats (Fig. 4).

Figure 4.

vWF-immunoreactive vessel density in the IBZ. (A) Schematic representation of a brain coronal section showing the ischemic core and IBZ. (B–E) Microscopic images of von Willebrand factor (vWF) immunoreactivity in representative rats treated with vehicle (B, D) or hUTC (C, E) acquired from the boxed area in (A) at 60 days post-MCA occlusion. (D) and (E) are high-magnification images from the boxed areas in (B) and (C), respectively. (F) Quantitative data showing the vWF-positive vessel density (number of vessels/mm²) in the IBZ. *p < 0.05. Scale bars: 500 μm (B, C) and 100 μm (D, E).

Discussion

Advanced age is associated with a decrease in brain plasticity and poor recovery from stroke (15). While previous studies have demonstrated beneficial effects of hUTC in experimental degenerative retinal and stroke models in young adult rodents (35,58), the efficacy of hUTC in aged rats with stroke was unknown. The present study demonstrates, for the first time, that intravenous administration of hUTC significantly improves neurological functional recovery in aged rats after stroke, which is accompanied by higher synaptophysin expression and vascular density in the IBZ. Hence, we conclude that the aged brain retains the capacity for neurorestoration in response to hUTC treatment.

Mesenchymal stem cells derived from human umbilical cord tissue have the ability to generate many cell types in vitro, including neurons and glia (19,39). These cells can transdifferentiate into neurons in experimental neurodegenerative diseases (31). However, Xiao et al. demonstrated that amelioration of neurological function following an intravenous injection of nonhematopoietic umbilical cord blood stem cells (nh-UCBSCs) into young rats after ischemic brain injury may be mediated by trophic actions that result in the reorganization of host nerve fiber connections within the injured brain (57). In the same study, it was observed that very few cells expressed the human nuclear marker within the brain, suggesting that the restorative effects of nh-UCBSCs may be mediated by mechanisms other than cell replacement. In the present study, only a very few hUTC were detected within the ischemic area. Double immunostaining revealed that these human cells did not coexpress neuronal antigens. In fact, it has been shown that subretinal infusion of hUTC preserves visual function in rats with retinal degeneration without neuronal differentiation, which is consistent with our current findings (35). Thus, our present data on the effectiveness of hUTC therapy for stroke obtained from older rats are consistent with the previous findings in young rats. Neither study presents evidence to support neuronal differentiation as the primary mechanism underlying the beneficial effects of hUTC (58). However, our results do favor the concept that these cells act as a paracrine mediator to elicit endogenous neurorestoration (10,13,32,40). Indeed, previous studies indicated that hUTC secrete several neurotrophic factors such as brain-derived neurotrophic factor (BDNF), fibroblast growth factor-2 (FGF-2), and interleukin-6 (IL-6), all of which have been shown to promote tissue repair after brain injury (32,35,47,55). Future studies are warranted to elucidate the dynamic distribution of hUTC, their secretion of paracrine factors, and their interactions with the host brain to foster neurorestoration.

We have previously shown higher synaptophysin expression and vascular density in young rats treated with hUTC after stroke (58). These processes may be key restorative mechanisms in response to hUTC treatment after the ischemic injury. However, age-associated impairments of synaptic plasticity and angiogenesis have been demonstrated by many experimental paradigms, which may lessen recovery from brain injury (2,26). Electrophysiological studies indicated that long-term potentiation/long-term depression (LTP/LTD), a cellular model of synaptic plasticity, is impaired during normal aging (8). In addition, although the aged brain is able to regain normal synaptic density after brain lesion, synaptogenesis is delayed in aged rats compared with young rats (2,26). Moreover, we and others have demonstrated that angiogenesis is impaired in aged rats after stroke (33,59). In the present study, animals treated with hUTC showed significantly higher synaptophysin expression and vessel density in the ischemic boundary area, which is associated with improved neurological functional recovery. Thus, although brain plasticity declines with age, our data suggest that the aged brain has the capacity for multiple regenerative processes in response to hUTC treatment, which likely contribute to functional recovery in the aged rat after stroke.

Intravenous administration of hUTC stimulates endogenous neural progenitor cell proliferation in young adult rats after stroke (58). However, in the present study, administration of hUTC resulted in a nonsignificant trend of increase in SVZ cell proliferation in the aged rats. The SVZ is the largest germinative layer of the adult brain (22), in which newly generated cells are capable of neuronal differentiation (1,17,45). Stroke triggers neurogenesis in the germinative regions in the young adult brain (4,28,38,59,60,62). However, stroke-induced neurogenesis is attenuated in the aged brain (11,15,27). Thus, the nonsignificant difference in SVZ cell proliferation in hUTC-treated aged animals is likely due to the natural attenuation of neurogenesis with increasing age. However, previous studies suggested that despite a reduction of cell proliferation in the SVZ of aged brain, the formation of mature striatal neurons after stroke appears similar in young and old rats (15), which argues against an intrinsic role of aging on neurogenesis after stroke. Thus, the effects of hUTC on endogenous neurogenesis and their relation to behavioral improvement in aged brain remain to be elucidated.

Neurological functional recovery after stroke is driven by neurorestorative processes including reorganization and rewiring of neuronal circuit, neurogenesis, and angiogenesis (5,13,14,41). We have previously demonstrated that intravenous administration of hUTC results in profound neurological functional improvement starting at 2 weeks after stroke onset, which is accompanied by enhancement of neurogenesis and synaptogenesis, as well as increased vessel density in the ischemic brain compared with the control (58). However, in aging rats, the behavioral benefits of hUTC's become evident in a delayed fashion. Advanced age may substantially influence the intrinsic remodeling capacity in response to ischemic insult (11,27), which may explain the delayed response to hUTC treatment as compared to young animals. Nevertheless, systemic hUTC treatment was still able to promote neurological functional improvement in aging rats after stroke.

In conclusion, for the first time, we demonstrate that intravenous administration of hUTC improves neurological function after stroke in a clinically relevant model of aged rats. We speculate that much of the beneficial effect of hUTC may be through the production of trophic factors, a mechanism that has been suggested to have the most immediate impact on stroke patients, rather than through cell replacement (12,13,24). As in the young animal treated with hUTC, in the aged animal, activation or enhancement of repair processes may be the underlying beneficial effect of hUTC in the treatment of stroke.

Footnotes

Acknowledgments

The research presented herein was funded by Advanced Technologies and Regenerative Medicine, LLC. The authors would like to acknowledge Yisheng Cui, M.D., Alex Zacharek, M.S., employees at Henry Ford Hospital, Anthony Kihm, Ph.D., Alex Harmon, Ph.D., David Colter, Ph.D., and Agnes Seyda, Ph.D., former employees at ATRM, for technical, editorial, and logistical support during the conduct of this study. K.H., B.K., M.R., and A.G. were employees of ATRM at the time the study was completed. (On December 30, 2012, ATRM merged into DePuy Orthopaedics, Inc.)

References

Anderson

D. J.

Stem cells and pattern formation in the nervous system: The possible versus the actual.

Neuron 30: 19–35; 2001.

Anderson

K. J.

Scheff

S. W.

DeKosky

S. T.

Reactive synaptogenesis in hippocampal area CA1 of aged and young adult rats.

J. Comp. Neurol. 252: 374–384; 1986.

Arien-Zakay

Lecht

Nagler

Lazarovici

Human umbilical cord blood stem cells: Rational for use as a neuroprotectant in ischemic brain disease.

Int. J. Mol. Sci. 11: 3513–3528; 2010.

Arvidsson

Kokaia

Lindvall

N-methyl-d-aspartate receptor-mediated increase of neurogenesis in adult rat dentate gyrus following stroke.

Eur. J. Neurosci. 14: 10–18; 2001.

Benowitz

L. I.

Carmichael

S. T.

Promoting axonal rewiring to improve outcome after stroke.

Neurobiol. Dis. 37: 259–266; 2010.

Bertoni-Freddari

Fattoretti

Giorgetti

Grossi

Balietti

Casoli

Di Stefano

Perretta

Alterations of synaptic turnover rate in aging may trigger senile plaque formation and neurodegeneration.

Ann. N. Y. Acad. Sci. 1096: 128–137; 2007.

Black

J. E.

Polinsky

Greenough

W. T.

Progressive failure of cerebral angiogenesis supporting neural plasticity in aging rats.

Neurobiol. Aging 10: 353–358; 1989.

Burke

S. N.

Barnes

C. A.

Neural plasticity in the ageing brain.

Nat. Rev. Neurosci. 7: 30–40; 2006.

Cao

F. J.

Feng

S. Q.

Human umbilical cord mesenchymal stem cells and the treatment of spinal cord injury.

Chin. Med. J. 122: 225–231; 2009.

10.

Chen

Sanberg

P. R.

Wang

Willing

A. E.

Sanchez-Ramos

Chopp

Intravenous administration of human umbilical cord blood reduces behavioral deficits after stroke in rats.

Stroke 32: 2682–2688; 2001.

11.

Chen

Zacharek

Wang

Katakowski

Roberts

Chopp

N-cadherin mediates nitric oxide-induced neurogenesis in young and retired breeder neurospheres.

Neuroscience 140: 377–388; 2006.

12.

Chen

Wang

Katakowski

Zhang

Chen

Gautam

S. C.

Chopp

Ischemic rat brain extracts induce human marrow stromal cell growth factor production.

Neuropathology 22: 275–279; 2002.

13.

Chopp

Treatment of neural injury with marrow stromal cells.

Lancet Neurol. 1: 92–100; 2002.

14.

Chopp

Zhang

Z. G.

Mechanisms underlying improved recovery of neurological function after stroke in the rodent after treatment with neurorestorative cell-based therapies.

Stroke 40: S143–145; 2009.

15.

Darsalia

Heldmann

Lindvall

Kokaia

Stroke-induced neurogenesis in aged brain.

Stroke 36: 1790–1795; 2005.

16.

Ding

D. C.

Shyu

W. C.

Lin

S. Z.

Mesenchymal stem cells.

Cell Transplant. 20: 5–14; 2009.

17.

Doetsch

Caille

Lim

D. A.

Garcia-Verdugo

J. M.

Alvarez-Buylla

Subventricular zone astrocytes are neural stem cells in the adult mammalian brain.

Cell 97: 703–716; 1999.

18.

Fan

C. G.

Zhang

Q. J.

Zhou

J. R.

Therapeutic potentials of mesenchymal stem cells derived from human umbilical cord.

Stem Cell Rev. 7: 195–207; 2011.

19.

Y. S.

Shih

Y. T.

Cheng

Y. C.

Min

M. Y.

Transformation of human umbilical mesenchymal cells into neurons in vitro.

J. Biomed. Sci. 11: 652–660; 2004.

20.

Futrell

Garcia

J. H.

Peterson

Millikan

Embolic stroke in aged rats.

Stroke 22: 1582–1591; 1991.

21.

Garbuzova-Davis

Willing

A. E.

Saporta

Bickford

P. C.

Gemma

Chen

Sanberg

C. D.

Klasko

S. K.

Borlongan

C. V.

Sanberg

P. R.

Novel cell therapy approaches for brain repair.

Prog. Brain Res. 157: 207–222; 2006.

22.

Gates

M. A.

Thomas

L. B.

Howard

E. M.

Laywell

E. D.

Sajin

Faissner

Gotz

Silver

Steindler

D. A.

Cell and molecular analysis of the developing and adult mouse subventricular zone of the cerebral hemispheres.

J. Comp. Neurol. 361: 249–266; 1995.

23.

Hernandez

T. D.

Schallert

Seizures and recovery from experimental brain damage.

Exp. Neurol. 102: 318–324; 1988.

24.

Hess

D. C.

Borlongan

C. V.

Stem cells and neurological diseases.

Cell Prolif. 41(Suppl 1): 94–114; 2008.

25.

Hof

P. R.

Morrison

J. H.

The aging brain: Morphomolecular senescence of cortical circuits.

Trends Neurosci. 27: 607–613; 2004.

26.

Hoff

S. F.

Scheff

S. W.

Benardo

L. S.

Cotman

C. W.

Lesion-induced synaptogenesis in the dentate gyrus of aged rats: I. Loss and reacquisition of normal synaptic density.

J. Comp. Neurol. 205: 246–252; 1982.

27.

Jin

Minami

Xie

Sun

Mao

X. O.

Wang

Simon

R. P.

Greenberg

D. A.

Ischemia-induced neurogenesis is preserved but reduced in the aged rodent brain.

Aging Cell 3: 373–377; 2004.

28.

Jin

Wang

Xie

Mao

X. O.

Zhu

Wang

Shen

Mao

Banwait

Greenberg

D. A.

Evidence for stroke-induced neurogenesis in the human brain.

Proc. Natl. Acad. Sci. USA 103: 13198–13202; 2006.

29.

Kalra

The influence of stroke unit rehabilitation on functional recovery from stroke.

Stroke 25: 821–825; 1994.

30.

Kammersgaard

L. P.

Jorgensen

H. S.

Reith

Nakayama

Pedersen

P. M.

Olsen

T. S.

Short- and long-term prognosis for very old stroke patients. The Copenhagen Stroke Study.

Age Ageing 33: 149–154; 2004.

31.

Koh

S. H.

Kim

K. S.

Choi

M. R.

Jung

K. H.

Park

K. S.

Chai

Y. G.

Roh

Hwang

S. J.

H. J.

Huh

Y. M.

Kim

H. T.

Kim

S. H.

Implantation of human umbilical cord-derived mesenchymal stem cells as a neuroprotective therapy for ischemic stroke in rats.

Brain Res. 1229: 233–248; 2008.

32.

A. J.

Suzuki

Mizukoshi

Imamura

Fibroblast growth factor-2 increases functional excitatory synapses on hippocampal neurons.

Eur. J. Neurosci. 16: 1313–1324; 2002.

33.

J. S.

Zhou

Y. L.

Liu

Gao

J. F.

Yang

X. K.

Zhao

Y. W.

Liu

Z. G.

Liu

J. X.

Angiogenesis of brain after ischemia/reperfusion injury of brain in aged rats and changes in expressions of basic fibroblast growth factor and transformation growth factor-β1.

Zhongguo Wei Zhong Bing Ji Jiu Yi Xue 22: 583–586; 2010.

34.

Chen

X. G.

Wang

Gautam

S. C.

Y. X.

Katakowski

Zhang

L. J.

Janakiraman

Chopp

Human marrow stromal cell therapy for stroke in rat: Neurotrophins and functional recovery.

Neurology 59: 514–523; 2002.

35.

Lund

R. D.

Wang

Girman

Holmes

Sauve

Messina

D. J.

Harris

I. R.

Kihm

A. J.

Harmon

A. M.

Chin

F. Y.

Gosiewska

Mistry

S. K.

Cells isolated from umbilical cord tissue rescue photoreceptors and visual functions in a rodent model of retinal disease.

Stem Cells 25: 602–611; 2007.

36.

Masliah

Fagan

A. M.

Terry

R. D.

DeTeresa

Mallory

Gage

F. H.

Reactive synaptogenesis assessed by synaptophysin immunoreactivity is associated with GAP-43 in the dentate gyrus of the adult rat.

Exp. Neurol. 113: 131–142; 1991.

37.

Michael

K. M.

Shaughnessy

Stroke prevention and management in older adults.

J. Cardiovasc. Nurs. 21: S21–26; 2006.

38.

Minger

S. L.

Ekonomou

Carta

E. M.

Chinoy

Perry

R. H.

Ballard

C. G.

Endogenous neurogenesis in the human brain following cerebral infarction.

Regen. Med. 2: 69–74; 2007.

39.

Mitchell

K. E.

Weiss

M. L.

Mitchell

B. M.

Martin

Davis

Morales

Helwig

Beerenstrauch

Abou-Easa

Hildreth

Troyer

Medicetty

Matrix cells from Wharton's jelly form neurons and glia.

Stem Cells 21: 50–60; 2003.

40.

Munoz

J. R.

Stoutenger

B. R.

Robinson

A. P.

Spees

J. L.

Prockop

D. J.

Human stem/progenitor cells from bone marrow promote neurogenesis of endogenous neural stem cells in the hippocampus of mice.

Proc. Natl. Acad. Sci. USA 102: 18171–18176; 2005.

41.

Murphy

T. H.

Corbett

Plasticity during stroke recovery: From synapse to behaviour.

Nat. Rev. Neurosci. 10: 861–872; 2009.

42.

Nakamura

Kobayashi

Ohashi

Ando

Age-changes of brain synapses and synaptic plasticity in response to an enriched environment.

J. Neurosci. Res. 56: 307–315; 1999.

43.

Nakayama

Jorgensen

H. S.

Raaschou

H. O.

Olsen

T. S.

The influence of age on stroke outcome. The Copenhagen Stroke Study.

Stroke 25: 808–813; 1994.

44.

Norris

C. M.

Halpain

Foster

T. C.

Reversal of age-related alterations in synaptic plasticity by blockade of l-type Ca²⁺ channels.

J. Neurosci. 18: 3171–3179; 1998.

45.

Palmer

T. D.

Markakis

E. A.

Willhoite

A. R.

Safar

Gage

F. H.

Fibroblast growth factor-2 activates a latent neurogenic program in neural stem cells from diverse regions of the adult CNS.

J. Neurosci. 19: 8487–8497; 1999.

46.

Paolucci

Antonucci

Troisi

Bragoni

Coiro

De Angelis

Pratesi

Venturiero

Grasso

M. G.

Aging and stroke rehabilitation.

a case-comparison study. Cerebrovasc. Dis. 15: 98–105; 2003.

47.

Patterson

S. L.

Abel

Deuel

T. A.

Martin

K. C.

Rose

J. C.

Kandel

E. R.

Recombinant BDNF rescues deficits in basal synaptic transmission and hippocampal LTP in BDNF knockout mice.

Neuron 16: 1137–1145; 1996.

48.

Riegelsberger

U. M.

Deten

Posel

Zille

Kranz

Boltze

Wagner

D. C.

Intravenous human umbilical cord blood transplantation for stroke: Impact on infarct volume and caspase-3-dependent cell death in spontaneously hypertensive rats.

Exp. Neurol. 227: 218–223; 2011.

49.

Rivard

Fabre

J. E.

Silver

Chen

Murohara

Kearney

Magner

Asahara

Isner

J. M.

Age-dependent impairment of angiogenesis.

Circulation 99: 111–120; 1999.

50.

Roger

V. L.

A. S.

Lloyd-Jones

D. M.

Adams

R. J.

Berry

J. D.

Brown

T. M.

Carnethon

M. R.

Dai

de Simone

Ford

E. S.

Fox

C. S.

Fullerton

H. J.

Gillespie

Greenlund

K. J.

Hailpern

S. M.

Heit

J. A.

P. M.

Howard

V. J.

Kissela

B. M.

Kittner

S. J.

Lackland

D. T.

Lichtman

J. H.

Lisabeth

L. D.

Makuc

D. M.

Marcus

G. M.

Marelli

Matchar

D. B.

McDermott

M. M.

Meigs

J. B.

Moy

C. S.

Mozaffarian

Mussolino

M. E.

Nichol

Paynter

N. P.

Rosamond

W. D.

Sorlie

P. D.

Stafford

R. S.

Turan

T. N.

Turner

M. B.

Wong

N. D.

Wylie-Rosett

Heart disease and stroke statistics— 2011 update: A report from the American Heart Association.

Circulation 123: e18–e209; 2011.

51.

Schauwecker

P. E.

Cheng

H. W.

Serquinia

R. M.

Mori

McNeill

T. H.

Lesion-induced sprouting of commissural/associational axons and induction of GAP-43 mRNA in hilar and CA3 pyramidal neurons in the hippocampus are diminished in aged rats.

J. Neurosci. 15: 2462–2470; 1995.

52.

Scheff

S. W.

Benardo

L. S.

Cotman

C. W.

Decline in reactive fiber growth in the dentate gyrus of aged rats compared to young adult rats following entorhinal cortex removal.

Brain Res. 199: 21–38; 1980.

53.

Secco

Moreira

Y. B.

Zucconi

Vieira

N. M.

Jazedje

Muotri

A. R.

Okamoto

O. K.

Verjovski-Almeida

Zatz

Gene expression profile of mesenchymal stem cells from paired umbilical cord units: Cord is different from blood.

Stem Cell Rev. 5: 387–401; 2009.

54.

Shen

L. H.

Chen

Cui

Zhang

Kapke

Savant-Bhonsale

Chopp

One-year follow-up after bone marrow stromal cell treatment in middle-aged female rats with stroke.

Stroke 38: 2150–2156; 2007.

55.

Tyler

W. J.

Pozzo-Miller

L. D.

BDNF enhances quantal neurotransmitter release and increases the number of docked vesicles at the active zones of hippocampal excitatory synapses.

J. Neurosci. 21: 4249–4258; 2001.

56.

Vendrame

Cassady

Newcomb

Butler

Pennypacker

K. R.

Zigova

Sanberg

C. D.

Sanberg

P. R.

Willing

A. E.

Infusion of human umbilical cord blood cells in a rat model of stroke dose-dependently rescues behavioral deficits and reduces infarct volume.

Stroke 35: 2390–2395; 2004.

57.

Xiao

Nan

Motooka

Low

W. C.

Transplantation of a novel cell line population of umbilical cord blood stem cells ameliorates neurological deficits associated with ischemic brain injury.

Stem Cells Dev. 14: 722–733; 2005.

58.

Zhang

Chopp

Gosiewska

Hong

Delayed administration of human umbilical tissue-derived cells improved neurological functional recovery in a rodent model of focal ischemia.

Stroke 42: 1437–1444; 2011.

59.

Zhang

R. L.

Wang

Zhang

Z. G.

Meng

Chopp

Functional recovery in aged and young rats after embolic stroke: Treatment with a phospho-diesterase type 5 inhibitor.

Stroke 36: 847–852; 2005.

60.

Zhang

Wang

Lapointe

Chopp

A nitric oxide donor induces neurogenesis and reduces functional deficits after stroke in rats.

Ann. Neurol. 50: 602–611; 2001.

61.

Zhang

R. L.

Chopp

Zhang

Z. G.

Jiang

Ewing

J. R.

A rat model of focal embolic cerebral ischemia.

Brain Res. 766: 83–92; 1997.

62.

Zhang

R. L.

Zhang

Z. G.

Zhang

Chopp

Proliferation and differentiation of progenitor cells in the cortex and the subventricular zone in the adult rat after focal cerebral ischemia.

Neuroscience 105: 33–41; 2001.

Intravenous Administration of Human Umbilical Tissue-Derived Cells Improves Neurological Function in Aged Rats after Embolic Stroke

Abstract

Keywords

Introduction

Materials and Methods

Preparation of hUTC

Experimental Protocol

Functional Outcome

Modified Neurological Severity Score (mNSS)

Adhesive Removal Test

Foot-Fault Test

Measurements of Infarct Volume

Immunohistochemistry

Statistical Analyses

Results

Mortality

Lesion Volume

Neurological Functional Outcome

Detection of Human Cells

Effects of hUTC on SVZ Cell Proliferation

Effects of hUTC on Synaptophysin

Effects of hUTC on Vascular Density

Discussion

Footnotes

Acknowledgments

References