Publications for Mugdha Joglekar
Publications for Mugdha Joglekar
08">[More Information]</a>
2016
Wong, W., Farr, R., Joglekar, M., Januszewski,
A., Hardikar, A. (2015). Probe-based Real-time
PCR Approaches for Quantitative Measurement
of microRNAs. Journal of Visualized
Experiments, 98, 1-12. <a
href="http://dx.doi.org/10.3791/52586">[More
Information]</a>
Joglekar, M., Januszewski, A., Jenkins, A.,
Hardikar, A. (2016). Circulating microRNA
Biomarkers of Diabetic Retinopathy. Diabetes,
65(1), 22-24. <a
href="http://dx.doi.org/10.2337/dbi15-0028">[M
ore Information]</a>
Joglekar, M., Trivedi, P., Kay, T., Hawthorne,
W., O'Connell, P., Jenkins, A., Hardikar, A.,
Thomas, H. (2016). Human islet cells are killed
by BID-independent mechanisms in response to
FAS ligand. Apoptosis, 21(4), 379-389. <a
href="http://dx.doi.org/10.1007/s10495-016-121
2-y">[More Information]</a>
2015
Farr, R., Januszewski, A., Joglekar, M., Liang,
H., McAulley, A., Hewitt, A., Thomas, H.,
Loudovaris, T., Kay, T., Jenkins, A., Hardikar,
A. (2015). A comparative analysis of
high-throughput platforms for validation of a
circulating microRNA signature in diabetic
retinopathy. Scientific Reports, 5, 1-13. <a
href="http://dx.doi.org/10.1038/srep10375">[Mo
re Information]</a>
Jenkins, A., Joglekar, M., Hardikar, A., Keech,
A., O'Neal, D., Januszewski, A. (2015).
Biomarkers in Diabetic Retinopathy. The Review
of Diabetic Studies, 12(1-2), 159-195. <a
href="http://dx.doi.org/10.1900/RDS.2015.12.15
9">[More Information]</a>
Ranjan, A., Joglekar, M., Hardikar, A. (2015).
Characterizing cellular identity at one cell
resolution. In G Hauptmann (Eds.), In Situ
Hybridization Methods, (pp. 541-548). New
York: Springer Science+Business Media. <a
href="http://dx.doi.org/10.1007/978-1-4939-230
3-8_28">[More Information]</a>
Farr, R., Joglekar, M., Hardikar, A. (2015).
Circulating microRNAs in Diabetes Progression:
Discovery, Validation, and Research Translation.
In Peter Igaz (Eds.), Circulating microRNAs in
Disease Diagnostics and their Potential
Biological Relevance, (pp. 215-244). Basel:
Springer International Publishing. <a
href="http://dx.doi.org/10.1007/978-3-0348-095
5-9_10">[More Information]</a>
Hardikar, A., Satoor, S., Karandikar, M.,
Joglekar, M., Puranik, A., Wong, W., Kumar, S.,
Limaye, A., Bhat, D., Januszewski, A., Keech,
A., Jenkins, A., et al (2015). Multigenerational
Undernutrition Increases Susceptibility to
Obesity and Diabetes that Is Not Reversed after
Dietary Recuperation. Cell Metabolism, 22(2),
312-319. <a
href="http://dx.doi.org/10.1016/j.cmet.2015.06.0
2014
Hardikar, A., Farr, R., Joglekar, M. (2014).
Circulating microRNAs: Understanding the
Limits for Quantitative Measurement by
Real-Time PCR. Journal of the American Heart
Association, 3(1), 1-4. <a
href="http://dx.doi.org/10.1161/JAHA.113.0007
92">[More Information]</a>
Satoor, S., Patil, D., Kristensen-Walker, H.,
Joglekar, M., Shouche, Y., Hardikar, A. (2014).
Manipulation and Assessment of Gut
Microbiome for Metabolic Studies. In Shree
Ram Singh, Vincenzo Coppola (Eds.), Mouse
Genetics: Methods and Protocols, (pp. 449-470).
New York: Springer.
Williams, M., Wong, W., Rixon, A., Satoor, S.,
Hardikar, A., Joglekar, M. (2014). Pdx1 (GFP/w)
Mice for Isolation, Characterization, and
Differentiation of Pancreatic Progenitor Cells.
In Shree Ram Singh, Vincenzo Coppola (Eds.),
Mouse Genetics: Methods and Protocols, (pp.
271-288). New York: Springer.
2013
Farr, R., Joglekar, M., Taylor, C., Hardikar, A.
(2013). Circulating non-coding RNAs as
biomarkers of beta cell death in diabetes.
Pediatric Endocrinology Reviews, 11(1), 14-20.
<a
href="http://www.ncbi.nlm.nih.gov/entrez/query.
fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract
&list_uids=24079075">[More Information]</a>
Farr, R., Taylor, C., Satoor, S., Williams, M.,
Joglekar, M. (2013). From Cradle to the Grave:
Tissue-specific microRNA signatures in
detecting clinical progression of diabetes.
MicroRNAs in Diabetes and Obesity
(Non-coding RNAs in Endocrinology), 1, 16-27.
<a
href="http://dx.doi.org/10.2478/micrnado-2013-0
004">[More Information]</a>
Joglekar, M., Hardikar, A. (2013). Human
Pancreatic Progenitors: Implications for Clinical
Transplantation in Diabetes. In Niranjan
Bhattacharya, Phillip Stubblefield (Eds.), Human
Fetal Tissue Transplantation, (pp. 237-249).
London: Springer.
2012
Taylor, C., Satoor, S., Rajan, A., Pereira e Cotta,
Publications for Mugdha Joglekar
M., Joglekar, M. (2012). A protocol for
measurement of noncoding RNA in human
serum. Experimental Diabetes Research, 2012
(9), 1-4. <a
href="http://dx.doi.org/10.1155/2012/168368">[
More Information]</a>
Ranjan, A., Joglekar, M., Atre, A., Patole, M.,
Bhonde, R., Hardikar, A. (2012). Cellular
detection of multiple antigens at single cell
resolution using antibodies generated from the
same species. Journal of Immunological
Methods, 379(1-2), 42-47. <a
href="http://dx.doi.org/10.1016/j.jim.2012.02.01
8">[More Information]</a>
Joglekar, M., Hardikar, A. (2012). Isolation,
Expansion, and Characterization of Human
Islet-Derived Progenitor Cells. In Shree Ram
Singh (Eds.), Methods in Molecular Biology:
Somatic Stem Cells, (pp. 351-366). New York,
United States: Humana Press.
Ranjan, A., Joglekar, M., Atre, A., Patole, M.,
Bhonde, R., Hardikar, A. (2012). Simultaneous
imaging of microRNA or mRNA territories with
protein territory in mammalian cells at single cell
resolution. RNA Biology, 9(7), 949-953. <a
href="http://dx.doi.org/10.4161/rna.20484">[Mo
re Information]</a>
2011
Sahu, S., Joglekar, M., Yang, S., Hardikar, A.
(2011). Cell Sources for Treating Diabetes. In
Ali Gholamrezanezhad (Eds.), Stem Cells in
Clinic and Research, (pp. 533-550). Rijeka,
Croatia: InTech Publishers.
Vaithilingam, V., Quayum, N., Joglekar, M.,
Jensen, J., Hardikar, A., Oberholzer, J.,
Guillemin, G., Tuch, B. (2011). Effect of
alginate encapsulation on the cellular
transcriptome of human islets. Biomaterials,
32(33), 8416-8425. <a
href="http://dx.doi.org/10.1016/j.biomaterials.20
11.06.044">[More Information]</a>
Sahu, S., Joglekar, M., Yang, S., Hardikar, A.
(2011). Gallbladder-derived islet stem cells. Stem
Cells. Vienna, Austria: Open Access Publishers.
Phadnis, S., Joglekar, M., DALVI, M.,
MUTHYALA, S., Nair, P., GHASKADBI, S.,
Bhonde, R., HARDIKAR, A. (2011). Human
bone marrow-derived mesenchymal cells
differentiate and mature into endocrine
pancreatic lineage in vivo. Cytotherapy, 13(3),
279-293. <a
href="http://dx.doi.org/10.3109/14653249.2010.
523108">[More Information]</a>
pancreatic islet beta cells. Cell Cycle, 9(20),
4077-4079. <a
href="http://www.ncbi.nlm.nih.gov/entrez/query.
fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract
&list_uids=20948307">[More Information]</a>
Joglekar, M., Hardikar, A. (2010). Human fetal
pancreatic progenitor cells. In Phillip
Stubblefield (Eds.), Clinical issues of fetal tissue
transplantation in medicine. Springer.
Joglekar, M., Wei, C., Hardikar, A. (2010).
Quantitative estimation of multiple miRNAs and
mRNAs from a single cell. Cold Spring Harbor
Protocols, 5(8). <a
href="http://dx.doi.org/10.1101/pdb.prot5478">[
More Information]</a>
2009
Parekh, V., Joglekar, M., Hardikar, A. (2009).
Differentiation of human umbilical cord
blood-derived mononuclear cells to endocrine
pancreatic lineage. Differentiation, 78(4),
232-240. <a
href="http://dx.doi.org/10.1016/j.diff.2009.07.00
4">[More Information]</a>
Ranjan, A., Joglekar, M., Hardikar, A. (2009).
Endothelial cells in pancreatic islet development
and function. Islets, 34, 523-528. <a
href="http://dx.doi.org/10.4161/isl.1.1.9054">[M
ore Information]</a>
Joglekar, M., Joglekar, V., Hardikar, A. (2009).
Expression of islet-specific microRNAs during
human pancreatic development. Gene Expression
Patterns, 9(2), 109-113. <a
href="http://dx.doi.org/10.1016/j.gep.2008.10.00
1">[More Information]</a>
Joglekar, M., Joglekar, V., Joglekar, S.,
Hardikar, A. (2009). Human fetal pancreatic
insulin-producing cells proliferate in vitro.
Journal of Endocrinology, 201(1), 27-36. <a
href="http://dx.doi.org/10.1677/JOE-08-0497">[
More Information]</a>
Dalvi, M., Umrani, M., Joglekar, M., Hardikar,
A. (2009). Human pancreatic islet progenitor
cells demonstrate phenotypic plasticity in vitro.
Journal of Biosciences, 34(4), 523-528. <a
href="http://dx.doi.org/10.1007/s12038-009-007
1-x">[More Information]</a>
2010
Sahu, S., Joglekar, M., Dumbre, R., Phadnis, S.,
Tosh, D., Hardikar, A. (2009). Islet-like cell
clusters occur naturally in human gall bladder
and are retained in diabetic conditions. Journal
of Cellular and Molecular Medicine, 13(5),
999-1000. <a
href="http://dx.doi.org/10.1111/j.1582-4934.200
8.00572.x">[More Information]</a>
Joglekar, M., Hardikar, A. (2010).
Epithelial-to-mesenchymal transition in
Kode, J., Mukherjee, S., Joglekar, M., Hardikar,
A. (2009). Mesenchymal stem cells:
Publications for Mugdha Joglekar
immunobiology and role in immunomodulation
and tissue regeneration. Cytotherapy, 11,
377-391. <a
href="http://dx.doi.org/10.1080/1465324090308
0367">[More Information]</a>
Joglekar, M., Ranjan, A., Hardikar, A. (2009).
Pancreas development and regeneration. In
Singh, S. R. (Eds.), Stem Cells: Organogenesis
and Cancer, (pp. 77-106). NIH, USA: Frontiers
in Bioscience.
Joglekar, M., Patil, D., Joglekar, V., Rao, G.,
Reddy, D., Mitala, S., Shouche, Y., Hardikar, A.
(2009). The miR-30 family microRNAs confer
epithelial phenotype to human pancreatic cells.
Islets, 1(2), 137-147. <a
href="http://dx.doi.org/10.4161/isl.1.2.9578">[M
ore Information]</a>
2007
Joglekar, M., Parekh, V., Mehta, S., honde, R.,
Hardikar, A. (2007). MicroRNA profiling of
developing and regenerating pancreas reveal
post-transcriptional regulation of neurogenin3.
Developmental Biology, 311(2), 603-612. <a
href="http://dx.doi.org/10.1016/j.ydbio.2007.09.
008">[More Information]</a>
Joglekar, M., Parekh, V., Hardikar, A. (2007).
New pancreas from old: microregulators of
pancreas regeneration. Trends in Endocrinology
and Metabolism, 18(10), 393-400. <a
href="http://www.ncbi.nlm.nih.gov/entrez/query.
fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract
&list_uids=18023200">[More Information]</a>
2006
Phadnis, S., Joglekar, M., Venkateshan, V.,
Ghaskadbi, S., Hardikar, A., Bhonde, R. (2006).
Human umbilical cord blood serum promotes
growth, proliferation, as well as differentiation of
human bone marrow-derived progenitor cells. In
Vitro Cellular & Developmental Biology.
Animal, 42(10), 283-286. <a
href="http://dx.doi.org/10.1290/0512087.1">[Mo
re Information]</a>