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Differentiation of Human Liver-Derived, Insulin-Producing Cells Toward the ß-Cell Phenotype

From the Department of Human Genetics and Molecular Medicine, Sackler School of Medicine, Tel Aviv University, Ramat Aviv, Tel Aviv, Israel

	ABSTRACT

TOP ABSTRACT RESEARCH DESIGN AND METHODS RESULTS DISCUSSION REFERENCES

 
ß-Cell transplantation is viewed as a cure for type 1 diabetes; however, it is limited by the number of pancreas donors. Human stem cells offer the promise of an abundant source of insulin-producing cells, given the existence of methods for manipulating their differentiation. We have previously demonstrated that the expression of the ß-cell transcription factor pancreatic duodenal homeobox 1 (PDX-1) in human fetal liver cells activates multiple aspects of the ß-cell phenotype. These cells, termed FH-B-TPN cells, produce insulin, release insulin in response to physiological glucose levels, and replace ß-cell function in diabetic immunodeficient mice. However, they deviate from the normal ß-cell phenotype by the lack of expression of a number of ß-cell genes, the expression of non–ß-cell genes, and a lower insulin content. Here we aimed to promote differentiation of FH-B-TPN cells toward the ß-cell phenotype using soluble factors. Cells cultured with activin A in serum-free medium upregulated expression of NeuroD and Nkx2.2 and downregulated paired box homeotic gene 6 (PAX-6). Glucokinase and prohormone convertase 1/3 were also upregulated, whereas pancreatic polypeptide and glucagon as well as liver markers were downregulated. Insulin content was increased by up to 33-fold, to 60% of the insulin content of normal ß-cells. The cells were shown to contain human C-peptide and release insulin in response to physiological glucose levels. Cell transplantation into immunodeficient diabetic mice resulted in the restoration of stable euglycemia. The cells continued to express insulin in vivo, and no cell replication was detected. Thus, the manipulation of culture conditions induced a significant and stable differentiation of FH-B-TPN cells toward the ß-cell phenotype, making them excellent candidates for ß-cell replacement in type 1 diabetes.

Abbreviations: 1-AT, 1-antitrypsin; Act-A, activin A; BrdU, 5-bromo-2-deoxyuridine; ELISA, enzyme-linked immunosorbent assay; HGF, hepatocyte growth factor; hTERT, catalytic subunit of human telomerase; KRB, Krebs-Ringer buffer; PAX-6, paired box homeotic gene 6; PC, prohormone convertase; PDX-1, pancreatic duodenal homeobox-1; PP, pancreatic polypeptide; RIA, radioimmunoassay; SFM, serum-free medium; STZ, streptozotocin

Type 1 diabetes is caused by autoimmune destruction of the pancreatic islet insulin-producing ß-cells. Insulin administration does not prevent long-term complications of the disease, as the optimal insulin dosage is difficult to adjust. Replacement of the damaged cells with regulated insulin-producing cells is considered the ultimate cure for type 1 diabetes. Transplantation of intact human pancreases or isolated islets has been severely limited by the scarcity of human tissue donors, and the search is on for an abundant source of human insulin-producing cells. Recent progress in stem cell biology has raised hopes for the generation of regulated insulin-producing cells by differentiation from various sources of stem/progenitor cells.

We recently showed that cells derived from a population of human fetal liver cells could be induced to acquire certain ß-cell properties after the expression of the transcription factor pancreatic duodenal homeobox 1 (PDX-1) (1). Our rationale for using fetal tissue was based on the expectation that it may be more enriched with stem/progenitor cells, which could be more pluripotent, than adult tissue. The primary cells were transduced with a viral vector encoding the catalytic subunit of human telomerase (hTERT) to prevent culture senescence (2), and the PDX-1 gene was introduced using a second viral vector into a single-cell clone of hTERT-expressing fetal liver cells, termed FH-B (1). The resulting cells, denoted as FH-B-TPN, were shown by RNA analyses to express multiple ß-cell genes as well as genes expressed in the non-ß islet cells, such as glucagon and pancreatic polypeptide (PP). In addition, they activated the expression of elastase, a marker of pancreatic exocrine cells, and continued to express a number of hepatic genes. The cells secreted insulin in response to physiological glucose levels; however, their insulin content was low, 2% of that of normal human islets. (Insulin content of isolated human islets varies widely [3]. Here we used an average figure of 10 µg/10⁶ cells for comparison.) After a 6-day incubation in serum-free medium (SFM), the insulin content was considerably elevated, to 2.7 µg per 10⁶ cells, representing 27% of the insulin content of normal human islets.

Although the expression of PDX-1 resulted in a profound phenotypic change in the fetal liver cells, their phenotype deviated from that of normal human ß-cells on several accounts: 1) they lacked expression of a number of ß-cell genes; 2) they expressed a number of non–ß-cell genes; and 3) their insulin content was lower. In addition, the initial study left a number of important issues open. Although the cells were correctly regulated by glucose, glucokinase mRNA was undetectable. The uniformity of cell phenotype was unknown, as the gene expression data were based on RNA analysis and the prevalence of the various markers in the population was not determined. Finally, the phenotypic stability in vivo was evaluated only by blood glucose measurement and lacked in situ data. Information was also needed on the residual cell replication in vivo.

In the current study, we evaluated the effect of a number of soluble factors in combination with SFM in enhancing the differentiation of FH-B-TPN cells toward the ß-cell phenotype. Our findings demonstrated that treatment with activin A (Act-A) in SFM results in enhanced differentiation of FH-B-TPN cells, as judged by an increase in insulin content and the expression of a number of ß-cell genes as well as a decrease in the expression of non–ß-cell genes. This phenotype was quite uniform in the cell population and was maintained for 2 months in vivo, as judged by in situ analyses. No evidence for cell replication in vivo was obtained. This phenotype renders FH-B-TPN cells as attractive candidates for cell therapy of type 1 diabetes.

	RESEARCH DESIGN AND METHODS

TOP ABSTRACT RESEARCH DESIGN AND METHODS RESULTS DISCUSSION REFERENCES

 
Cell culture.
FH-B cells were cultured as previously described (1) in Dulbecco’s modified Eagle’s medium containing 25 mmol/l glucose and supplemented with 10% fetal bovine serum, 100 units/ml penicillin, 100 µg/ml streptomycin, 5 µmol/l hydrocortisone, and 5 µg/ml insulin. FH-B-TPN cells were maintained in the same culture medium, except without the hydrocortisone and insulin (complete medium). For incubation in SFM, the cells were placed in Dulbecco’s modified Eagle’s medium containing antibiotics in the presence of 10 µg/ml insulin, 5.5 µg/ml transferrin, and 5 ng/ml selenium (Sigma-Aldrich, Steinheim, Germany). Treatment with Act-A (Cytolab/PreproTech Asia, Rehovot, Israel), betacellulin (R&D Systems, Minneapolis, MN), nicotinamide (Sigma-Aldrich), exendin-4 (Sigma-Aldrich), and hepatocyte growth factor (HGF; Sigma-Aldrich) was at the concentrations detailed for each experiment. The experiments described herein used cells between passages 9 and 22 (passage 1 is defined as the first passage after neomycin selection after the introduction of PDX-1).

Insulin and human C-peptide secretion and cell content.
Insulin secretion was measured by static incubation, as previously described (4). Cells were plated in 24-well plates at 5 x 10⁴ cells per well. The cells were preincubated for 1 h in Krebs-Ringer buffer (KRB) then incubated for 30 min in KRB containing 0.5 mmol/l 1-isobutyl 3-methylxanthine and glucose at various concentrations. The cells were then extracted in acetic acid, and the amount of insulin in the buffer and cell extract was determined by radioimmunoassay (RIA) using the INSIK-5 kit (DiaSorin, Vercelli, Italy), according to the manufacturer’s instructions. This assay has <20% cross-reactivity with proinsulin. In addition, insulin content was determined using an enzyme-linked immunosorbent assay (ELISA) kit (Mercodia, Uppsala, Sweden) that recognizes only mature insulin. Insulin content was normalized to total cellular protein, measured by the Bio-Rad protein assay kit (Hercules, CA). Human C-peptide in the cell extract was determined using an RIA (DiaSorin) or ELISA (Mercodia) kit, according to the manufacturer’s instructions.

RNA analyses.
Total RNA was extracted from cultured cells and human pancreatic islets (obtained through the Juvenile Diabetes Research Foundation Islet Distribution Program) using a commercial kit (High Pure RNA isolation kit, Roche, Mannheim, Germany). Specific transcripts were analyzed with the SuperScript III (Invitrogen, Carlsbad, CA) RT-PCR kit and used according to the manufacturer’s instructions. cDNA was amplified for 40 cycles (94°C for 45 s, annealing for 45 s, and 72°C for 40 s) using the primer pairs and annealing temperatures listed in Table 1. PCR products were separated by electrophoresis in 1.5% agarose gels and visualized by ethidium bromide staining.

Histological analyses.
Cells plated in 24-well plates on sterilized coverslips were fixed in 4% paraformaldehyde. For nuclear antigens, cells were permeabilized with 0.25% NP-40 for 10 min. Cells were blocked for 10 min at room temperature in 1% BSA, 10% fetal bovine serum, and 0.2% saponin and incubated overnight at 4°C, with the primary antibody diluted in blocking solution (Table 2). All the antibodies were calibrated using FH-B, COS7, or 293T cells as negative controls. The bound antibody was visualized with a fluorescent secondary antibody (Biomeda, Foster City, CA) (Table 2) under a Zeiss confocal microscope. Nuclei were visualized with DAPI (Roche) staining for 5 min at room temperature. Kidney tissue was fixed in 4% paraformaldehyde, embedded in paraffin, and sectioned. Sections were rehydrated, washed in PBS, and unmasked (if needed) in unmasking solution (Vector, Burlingame, CA), according to the manufacturer’s instructions. Sections were blocked for 2 h in 0.2% Tween 20 and 0.2% gelatin, incubated overnight at 4°C with primary antibodies and then for 2 h at room temperature with the secondary antibodies (Table 2), stained with DAPI, and mounted. BrdU staining was performed as previously described (5).

	RESULTS

TOP ABSTRACT RESEARCH DESIGN AND METHODS RESULTS DISCUSSION REFERENCES

View larger version (9K): [in this window] [in a new window]   FIG. 1. Effect of Act-A concentration on insulin content in FH-B-TPN cells. FH-B-TPN cells were incubated with the indicated concentrations of Act-A in complete medium for 6 days. Insulin in cell extracts was quantitated by RIA. Data are means ± SD (n = 3).

View larger version (98K): [in this window] [in a new window]   FIG. 2. RT-PCR analysis of gene expression in FH-B and FH-B-TPN cells treated with various culture media. Cells were grown for >7 days in complete medium (CM), 3 days in CM containing Act-A, 6 days in SFM, 6 days in SFM, and then 3 days in Act-A in SFM, or tested for phenotypic stability (Stb) 10 days after the shift from the last medium into CM. RNA extracted from the cells was analyzed by RT-PCR with the indicated primers in comparison with a negative (–) and positive (+; genomic DNA for 1-AT and human islet RNA for the rest) control. GK, glucokinase.

View larger version (54K): [in this window] [in a new window]   FIG. 3. Immunofluorescence analyses of protein expression in FH-B-TPN cells treated with SFM for 6 days followed by Act-A in SFM for 3 days (Treated) compared with cells grown in complete medium (Untreated). Indicated antigens were visualized with Cy2- (green) and Cy3- (red) conjugated secondary antibodies. All nuclei were labeled blue with DAPI. The percent of positive cells shown on each panel is based on counting >300 cells in multiple fields. Bar = 10 µm. GK, glucokinase.

Insulin secretion, which was previously shown to be glucose responsive in the physiological concentration range in FH-B-TPN cells in both complete medium and SFM (1), was also normal in cells grown in the presence of Act-A, both during 3 days in complete medium and after Act-A treatment during the last 3 of 9 days in SFM (Fig. 4). The maximal secretion at 20 mmol/l glucose of cells treated with SFM plus Act-A represented 1.1% of their insulin content, similar to that in normal islets.

View larger version (16K): [in this window] [in a new window]   FIG. 4. Glucose-induced insulin secretion in FH-B-TPN cells treated with Act-A. Cells were treated with Act-A in complete medium for 3 days (A) or with SFM for 6 days and then Act-A for 3 days in SFM (B). Insulin secretion was studied in KRB containing 0.5 mmol/l 1-isobutyl 3-methylxanthine and the indicated concentrations of glucose during a 30-min incubation. Insulin in the medium was quantitated by ELISA and normalized to cell number. Data are means ± SD (n = 3).

To assess the functional stability of the FH-B-TPN cells in vivo after in vitro treatment with SFM plus Act-A, cells were transplanted under the renal capsule of STZ-induced diabetic NOD-scid mice. As seen in Fig. 5A, blood glucose levels were lowered starting 2 days after transplantation. Glycemia was normalized thereafter, and stable blood glucose levels were maintained for >2 months, until the experiment was terminated for histological analyses. No hypoglycemia developed by the end of the experiment. Before the mice were killed, they were subjected to a glucose tolerance test, which demonstrated a normal rate of glucose clearance (Fig. 5B). Human C-peptide ELISA detected serum levels of 0.31–0.84 ng/ml (compared with 0.27 ng/ml in a human serum control and no detectable signal in normal mouse serum). Histological analyses detected insulin and human C-peptide immunofluorescence staining in cells positively identified as human using human-specific anti–heat shock protein 27 antibodies with no cross-reactivity to mouse (Fig. 5C). No BrdU-labeled cells were detected in the transplants, indicating that little or no cell replication occurred in the transplanted cells at this time point (Fig. 5C).

View larger version (100K): [in this window] [in a new window]   FIG. 5. Correction of glycemia in NOD-scid mice transplanted with FH-B-TPN cells after treatment with Act-A in SFM. Mice made diabetic by STZ treatment were injected with 2 x 106 cells at passage 17 under the left renal capsule. Fed blood glucose was measured twice a week. A: Blood glucose levels. Data are means ± SD (n = 7). The dashed line marks the upper end of normal fed blood glucose levels. Mice transplanted with 5 x 106 FH-B cells died within 6 days of the transplantation. B: Glucose tolerance test performed on four of the seven mice shown in A on posttransplantation day 65. Each curve represents an individual mouse, identified by number. Two normal mice are included as controls. C: Histological analyses of the transplanted cells. Shown are a kidney with transplanted cells seen at its top right corner (a), hematoxylin and eosin staining of a kidney section with the transplanted cells in the top half (b), and immunofluorescence analyses of adjacent sections with the indicated antibodies, as visualized with Cy3-conjugated secondary antibodies (c–f). All nuclei are labeled blue with DAPI. In subpanel c, the dashed line marks the boundary between the transplanted cells and the kidney parenchyma. A single nucleus labeled by BrdU is seen in the latter. Bar = 50 µm.

	DISCUSSION

TOP ABSTRACT RESEARCH DESIGN AND METHODS RESULTS DISCUSSION REFERENCES

In one significant finding, the cellular insulin content was increased by up to 33-fold to over 6% of cellular protein content, which represents 60% of the content of normal human pancreatic islets. To our knowledge, this is the highest content reported to date for human insulin–producing cells derived from stem/progenitor cells. These amounts of insulin result from biosynthesis in the cells rather than uptake from the medium, as judged by the following criteria: 1) no insulin was detected in FH-B cells cultured in the same conditions, 2) insulin was detected in FH-B-TPN cells cultured in complete medium that was not supplemented with insulin, 3) insulin mRNA was detected in the cells, and 4) human C-peptide was detected in the cells by ELISA and immunofluorescence, as well as in the culture medium and in the serum of mice transplanted with these cells. The modified cells maintained a normal glucose-induced insulin secretory profile in the physiological concentration range, which was already observed in FH-B-TPN cells cultured in complete medium (1). The insulin content of isolated human islets is known to vary widely (3). Eizirik et al. (7) cited a value of 22.9 ng/islet, which would represent 11.45 µg/10⁶ cells, assuming an islet contains an average of 2,000 cells. Here we used a convenient measuring stick of 10 µg/10⁶ cells for comparison.

The differentiated phenotype achieved by these culture conditions was partly stable in vitro after the return of the cells to complete medium for 10 days. However, a more relevant test of phenotypic stability is in vivo cell function. As judged by assays performed >2 months after transplantation, the transplanted cells were capable of maintaining euglycemia and responding to a glucose tolerance test in a normal time course. In addition, intense immunofluorescence for insulin and human C-peptide demonstrated that a stable, highly differentiated state of the cells was maintained for prolonged periods in a nonpancreatic site in vivo. In one interesting finding, the immunostaining analyses also revealed the absence of cell replication in vivo, as judged by the lack of BrdU incorporation, indicating that the constitutive expression of hTERT did not overcome signals of contact inhibition by itself.

The molecular mechanism by which cell culture in the presence of Act-A in SFM leads to FH-B-TPN cell differentiation remains to be elucidated. The activity of Act-A required the expression of PDX-1, as Act-A by itself did not induce differentiation of FH-B cells. It was interesting that the other factors tested (betacellulin, nicotinamide, and HGF) did not significantly increase FH-B-TPN cell differentiation, as judged by insulin content, and did not potentiate the effect of Act-A at the concentrations used here. The effect of SFM is likely attributable to serum removal rather than the presence of insulin, transferrin, and selenium in the medium. Serum removal may eliminate both growth factors and inhibitors of cell differentiation. The changes in cell doubling time suggest that further cell differentiation is coupled with withdrawal from the cell cycle. Act-A is a cytokine of the transforming growth factor-ß superfamily, which is responsible for pleiotropic effects, including cell proliferation, differentiation, and apoptosis (8). The factor and its receptor are expressed in multiple cell types in the embryo and the adult, including islet - and -cells (9). Follistatin, an antagonist of Act-A, has been shown to block development of the rat endocrine pancreas and promote exocrine pancreas development (10). Mouse models expressing a dominant-negative form of Act-A receptor II manifest abnormalities in endocrine pancreas development (11,12). Act-A together with betacellulin (13) or HGF (6) convert the exocrine pancreas cell line AR42J into insulin-producing cells and induce differentiation of human fetal pancreas endocrine cells (14). Taken together, these findings support a role for Act-A in ß-cell development and differentiation. In addition, Act-A inhibits hepatocyte growth (15,16), which is confirmed by our findings of an increase in cell doubling time obtained with Act-A in SFM. The activity of the Act-A receptor is mediated through intracellular proteins known as Smads, which translocate to the cell nucleus and modulate gene transcription (8). In comparing the pattern of gene expression obtained with SFM to that of SFM plus Act-A (Fig. 2, lanes 7 and 8), the major changes observed were the increase in NeuroD and PC1/3 and the decrease in Nkx2.2 expression induced by Act-A. It is possible that these changes are responsible for the close to threefold increase in insulin content found in the cells treated with Act-A. The fact that treatment with Act-A after a 6-day incubation in SFM resulted in the highest insulin content obtained in this study suggests a need for a sequential order of events, in which an increase in Nkx2.2 and a decrease in PAX-6 expression is followed by a marked increase in NeuroD expression, to maximize the cellular insulin biosynthesis and storage capacities. Microarray analyses of the entire spectrum of changes in gene expression affected by this treatment may provide further mechanistic insights. Nevertheless, the properties of FH-B-TPN cells after the differentiation affected by Act-A in SFM render them excellent candidates for the development of an abundant cell source for ß-cell replacement therapy of type 1 diabetes. The presence of a constitutive hTERT gene in FH-B-TPN cells may represent an increased risk of neoplasia compared with cells lacking hTERT expression. However, FH-B cells were extensively tested both in vitro and in vivo and exhibited no oncogenicity (2). FH-B-TPN cells manifest a decreased proliferation rate compared with FH-B cells, undergo contact inhibition in vitro (Fig. 3), and do not label with BrdU in vivo (Fig. 5). Nevertheless, the use of cell encapsulation or suicide genes may be needed to increase the safety of their transplantation.

	ACKNOWLEDGMENTS

 
This work was supported by National Institutes of Health Grant DK-52956-06 to S.E.

We thank Mark Magnuson and Donald Steiner for antibodies. The Nkx2.2 monoclonal antibody developed by T. Jessell was obtained from the Developmental Studies Hybridoma Bank.

This work was performed in partial fulfillment of the requirements for the doctoral degree of Michal Zalzman.

Received for publication March 6, 2005 and accepted in revised form May 31, 2005

	REFERENCES

TOP ABSTRACT RESEARCH DESIGN AND METHODS RESULTS DISCUSSION REFERENCES

 

1. Zalzman M, Gupta S, Giri RK, Berkovich I, Sappal BS, Karnieli O, Zern MA, Fleischer N, Efrat S: Reversal of hyperglycemia in mice by using human expandable insulin-producing cells differentiated from fetal liver progenitor cells. Proc Natl Acad Sci U S A 100:7253–7258, 2003[Abstract/Free Full Text]
2. Wege H, Le HT, Chui MS, Liu L, Wu J, Giri R, Malhi H, Sappal BS, Kumaran V, Gupta S, Zern MA: Telomerase reconstitution immortalizes human fetal hepatocytes without disrupting their differentiation potential. Gastroenterology 12:432–444, 2003
3. Brandhorst H, Brandhorst D, Brendel MD, Hering BJ, Bretzel RG: Assessment of intracellular insulin content during all steps of human islet isolation procedure. Cell Transplant 7:489–495, 1998[Medline]
4. Fleischer N, Chen C, Surana M, Leiser M, Rossetti L, Pralong W, Efrat S: Functional analysis of a conditionally transformed pancreatic beta-cell line. Diabetes 47:1419–1425, 1998[Abstract/Free Full Text]
5. Berkovich I, Efrat S: Inducible and reversible ß-cell autoimmunity and hyperplasia in transgenic mice expressing a conditional oncogene. Diabetes 50:2260–2267, 2001[Abstract/Free Full Text]
6. Zhang YQ, Kanzaki M, Furukawa M, Shibata H, Ozeki M, Kojima I: Involvement of Smad proteins in the differentiation of pancreatic AR42J cells induced by activin A. Diabetologia 42:719–727, 1999[Medline]
7. Eizirik DL, Korbutt GS, Hellerstrom C: Prolonged exposure of human pancreatic islets to high glucose concentrations in vitro impairs the beta-cell function. J Clin Invest 90:1263–1268, 1992
8. Chen YG, Lui HM, Lin SL, Lee JM, Ying SY: Regulation of cell proliferation, apoptosis, and carcinogenesis by activin. Exp Biol Med (Maywood) 227:75–87, 2002[Abstract/Free Full Text]
9. Yasuda H, Inoue K, Shibata H, Takeuchi T, Eto Y, Hasegawa Y, Sekine N, Totsuka Y, Mine T, Ogata E, et al: Existence of activin-A in A- and D-cells of rat pancreatic islet. Endocrinology 133:624–630, 1993[Abstract]
10. Miralles F, Czernichow P, Scharfmann R: Follistatin regulates the relative proportions of endocrine versus exocrine tissue during pancreatic development. Development 125:1017–1024, 1998[Abstract]
11. Yamaoka T, Idehara C, Yano M, Matsushita T, Yamada T, Ii S, Moritani M, Hata J, Sugino H, Noji S, Itakura M: Hypoplasia of pancreatic islets in transgenic mice expressing activin receptor mutants. J Clin Invest 102:294–301, 1998[Medline]
12. Shiozaki S, Tajima T, Zhang YQ, Furukawa M, Nakazato Y, Kojima I: Impaired differentiation of endocrine and exocrine cells of the pancreas in transgenic mouse expressing the truncated type II activin receptor. Biochim Biophys Acta 1450:1–11, 1999[Medline]
13. Mashima H, Ohnishi H, Wakabayashi K, Mine T, Miyagawa J, Hanafusa T, Seno M, Yamada H, Kojima I: Betacellulin and activin A coordinately convert amylase-secreting pancreatic AR42J cells into insulin-secreting cells. J Clin Invest 97:1647–1654, 1996[Medline]
14. Demeterco C, Beattie GM, Dib SA, Lopez AD, Hayek A: A role for activin A and betacellulin in human fetal pancreatic cell differentiation and growth. J Clin Endocrinol Metab 85:3892–3897, 2000[Abstract/Free Full Text]
15. Yasuda H, Mine T, Shibata H, Eto Y, Hasegawa Y, Takeuchi T, Asano S, Kojima I: Activin A: an autocrine inhibitor of initiation of DNA synthesis in rat hepatocytes. J Clin Invest 92:1491–1496, 1993
16. Ho J, de Guise C, Kim C, Lemay S, Wang X-F, Lebrun J-J: Activin induces hepatocyte cell growth arrest through induction of the cyclin-dependent kinase inhibitor p15INK4B and Sp1. Cell Signal 16:693–701, 2004[Medline]

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This Article Abstract Full Text (PDF) Purchase Article View Shopping Cart Alert me when this article is cited Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Permissions Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Zalzman, M. Articles by Efrat, S. Search for Related Content PubMed PubMed Citation Articles by Zalzman, M. Articles by Efrat, S. Social Bookmarking                What's this?