Category Archives: Cell Therapy

WELCOME TO PROGENCELL-STEM CELL THERAPIES

Congratulations on taking the first step to improving your health!

PROGENCELL offers stem cell protocols with effective results. Many years of research and experience have resulted in substantial improvements in the health and conditions of patients with various diseases, even where other treatments have failed.

With the highest quality protocols, Progencell uses stem cells directly from the patient (autologous adult stem cells) in order to improve their health. The patients medical condition creates the appropriate environment in the body, resulting in a personalized therapy created specially for him.

We offer patients with certain degenerative diseases an opportunity to improve their health through cellular therapy, correcting their medical conditions from the source by regenerating the tissues and organs that are causing the ailments. Since we use stem cells from the patient, this therapy has no risk of tissue rejection, and minimal secondary effects.

Read more:
Progencell | Stem Cell Therapy | Tijuana Mexico

Bengaluru, Feb 25, 2015, dhns:

Two courses of stem cell therapy have helped Ashok Kumar, 59, who suffered from tremors and rigidity due to Parkinsons disease, recover completely, much to the joy of his family.

The man was brought inside my cabin in a wheelchair. He was unable to even sit on the chair without support. Today, he walks independently. Stem cell therapy has made it possible for him, said Dr Naseem Sadiq, Director, Plexus Neuro and Stem Cell Research Centre, who began treating Kumar in October, last year.

Previously, medication and surgical procedure were the only treatment option for Parkinsons disease. Medication in the long-term often lacks effectiveness and may cause side effects, while surgery is not always feasible. Lately, stem cell therapy has turned out to be a boon for patients with Parkinsons, Dr Sadiq said.

Kumar is among the few who have benefited from stem cell therapy. However, though the State has been reporting an increase in the number of registered stem cell donors, it is far behind sufficient as the genetic match between donor and recipient could be anywhere between one in 10,000 and one in two million, according to experts.

Speaking to Deccan Herald, Raghu Rajgopal, co-founder, Datri, a registry for stem cell donation, said, The response we get from Karnataka when we conduct stem cell camps is great. We see a lot of people and registering with us.

As many as 6,000 people have registered from the State under the Datri registry. A total of 72,000 people have registered across the country. In Kerala, 11,000 have signed up, the highest so far, he said.

Among the common myths are that by donating stem cells one turns infertile and weak, have increased chances of cancer and also that there would be excess loss of blood, he said.

According to studies, over one lakh people are diagnosed with Leukemia (blood cancer) and other blood disorders every year in India.

The Indian Council of Medical Research has predicted that by the end of 2015, Leukemia cases will reach an estimated 1,17,649 and 1,32,574 by 2020. Stem cell therapy is a widely used treatment mechanism for Leukemia.

Go here to read the rest:
Stem cell therapy a boon for Parkinson patients

Figure 1. Stem CellRecruiting Hydrogels Based on Self-Assembling Peptides

The Materials for Biomaterials session Best Contribution Award presented by Steve Zinkle goes to Yongmee Jung, Korea Institute of Science and Technology, for the oral presentation Self-assembling peptide nanofiber coupled with neuropeptide substance P for stem cell recruitment.

As a winner of the above Materials Today Asia Contribution Award, Yongmee Jung and Soo Hyun Kim discuss their work with us.

Stem cellbased therapy in regenerative medicine may be one of the best approaches for wound healing and tissue regeneration. Many studies have shown that the trophic effects of transplanted stem cells enhance the treatment of lung, liver, and skin injuries, as well as myocardial infarction [1]. However, although stem cell transplantationincluding cell isolation and cell culture in vitroresults in a good prognosis, there are some limitations, such as high cost, invasiveness, the shortage of cell sources, and the risk of tumorigenesis [2]. To overcome these limitations, technologies for recruiting endogenous stem cells to the site of injury may provide another promising approach, mimicking in situ tissue regeneration by the bodys own wound healing process. Unlike cell-based therapies, this strategy does not need outside cell sources or in vitro cell manipulation. Host stem cells can be mobilized using granulocyte colony-stimulating factor (G-CSF), granulocyte-macrophage colony-stimulating factor (GM-CSF), or stromal cellderived factor-1 alpha (SDF-1), each of which upregulates adhesion molecules and activates chemokine signaling [3]. It has been reported that substance P (SP), another candidate for recruitment of host stem cells, is an injury-inducible factor that acts early in the wound healing process to mobilize CD29+ stromal-like cells, and thus could be used for tissue regeneration [1].

To achieve effective delivery of SP for an extended period and improve the engraftment of recruited cells at the injured site, scaffolds can be constructed from hydrogels with microenvironments similar to the native tissue. Of particular interest are self-assembling peptide (SAP)based hydrogels, which are typically composed of alternating hydrophilic and hydrophobic amino acids organized into 510 nm fibers and assembled into three-dimensional nanofibrous structures under in vivo conditions [4]. The resulting structure resembles nanostructured environments such as collagen hierarchical structures that promote adhesion, proliferation, and differentiation of cells. Furthermore, SAP is versatile enough to incorporate specific motifs based on the desired function with chemical coupling by peptide bond [5].

Recently, we designed bioactive peptide hydrogels that are able to recruit mesenchymal stem cells by coupling SAP to SP. The mixture of SAP and SP-coupled SAP can successfully maintain its nanofibrous structure and be assembled into a 3D scaffold at physiological conditions.

We confirmed the ability of this SP-coupled SAP to attract stem cells both by in vitro cell migration assay and by in vivo real-time cell tracking assay. In vitro, many cells migrated through the 8-m membrane pores and settled onto the lower surfaces of Transwell plates under the influence of SP-coupled SAP. In vivo, we injected the hydrogels into the subcutaneous tissue in nude mice and injected labeled human mesenchymal stem cells (hMSCs) into the tail vein. The migration of the injected cells was tracked in real time using a multispectral imaging system, which demonstrated that the labeled hMSCs supplied via intravenous injection were recruited to the hydrogel-injected site (Figure) [6]. We then applied our bioactive peptide hydrogels, SAP coupled with SP, to several disease models to evaluate their stem cell recruitment abilities and treatment effects on injured tissues. We have studied the effects of these hydrogels on animal models of ischemic hind limb, calvarial defect, myocardial infarction, osteoarthritis, and skin wounds. We observed in each case that in the group treated with SP-coupled peptide hydrogels, many MSCs were recruited to the injured sites, and cell apoptosis and fibrosis of injured tissues were both conspicuously decreased. Moreover, the regeneration of site-specific tissues was enhanced with the injection of stem cellrecruiting peptide hydrogels in various defect models, and tissue functions were accordingly improved without cell transplantation [2, 5, 6]. In conclusion, we have developed injectable bioactive peptides that can recruit MSCs and have evaluated their therapeutic potential on animal defect models. By applying these peptide hydrogels, we were able to deliver SP over an extended period and provide 3D microenvironments to injured regions, allowing bioactive peptides to recruit MSCs successfully, prevent cell apoptosis, and promote tissue regeneration leading to a full recovery of defects. We expect that stem cellrecruiting hydrogels based on SAP could be one of the most powerful tools for tissue regeneration without cell transplantation through the recruitment of endogenous stem cells.

This work was supported by the KIST Institutional Program

1. H. S. Hong, et al., Nat. Med., 15 (2009), pp. 425435 2. J. H. Kim, et al., Biomaterials, 34 (2013), pp. 16571668 3. T. Lapidot, I. Petit, Exp. Hematol., 30 (2002), pp. 973981 4. S. Zhang, et al., Semin. Cancer Biol., 15 (5) (2005), pp. 413420 5. J. E. Kim, et al., Int. J. Nanomedicine, 9 (Suppl 1) (2014), pp. 141157 6. S. H. Kim, et al., Tissue Eng. Part A, E-Pub (2014)

Read more from the original source:
Stem cellrecruiting hydrogels based on self-assembling peptides for tissue regeneration

Abstract Introduction

Aromatic (ar-) turmerone is a major bioactive compound of the herb Curcuma longa. It has been suggested that ar-turmerone inhibits microglia activation, a property that may be useful in treating neurodegenerative disease. Furthermore, the effects of ar-turmerone on neural stem cells (NSCs) remain to be investigated.

We exposed primary fetal rat NSCs to various concentrations of ar-turmerone. Thereafter, cell proliferation and differentiation potential were assessed. In vivo, nave rats were treated with a single intracerebroventricular (i.c.v.) injection of ar-turmerone. Proliferative activity of endogenous NSCs was assessed in vivo, by using noninvasive positron emission tomography (PET) imaging and the tracer [18F]-fluoro-L-thymidine ([18F]FLT), as well as ex vivo.

In vitro, ar-turmerone increased dose-dependently the number of cultured NSCs, because of an increase in NSC proliferation (P<0.01). Proliferation data were supported by qPCR-data for Ki-67 mRNA. In vitro as well as in vivo, ar-turmerone promoted neuronal differentiation of NSCs. In vivo, after i.c.v. injection of ar-turmerone, proliferating NSCs were mobilized from the subventricular zone (SVZ) and the hippocampus of adult rats, as demonstrated by both [18F]FLT-PET and histology (P<0.05).

Both in vitro and in vivo data suggest that ar-turmerone induces NSC proliferation. Ar-turmerone thus constitutes a promising candidate to support regeneration in neurologic disease.

Curcumin and ar-turmerone are the major bioactive compounds of the herb Curcuma longa. Although many studies have demonstrated curcumin to possess antiinflammatory and neuroprotective properties (reviewed by [1]), to date, the effects of ar-turmerone remain to be elucidated. For example, antitumor properties, exerted via the induction of apoptosis [2] and inhibition of tumor cell invasion [3], have been attributed to ar-turmerone. Park et al. [4,5] recently suggested that ar-turmerone also possesses antiinflammatory properties resulting from the blockade of key signaling pathways in microglia. Because microglia activation is a hallmark of neuroinflammation and is associated with various neurologic disorders, including neurodegenerative diseases [6,7] and stroke [8,9], ar-turmerone constitutes a promising therapeutic agent for various neurologic disorders.

The regenerative potential of endogenous neural stem cells (NSCs) plays an important role in neurodegenerative disease and stroke. Endogenous NSCs are mobilized by cerebral ischemia [10] as well as by various neurodegenerative diseases [11,12], although their intrinsic regenerative response is insufficient to enable functional recovery. The targeted (that is, pharmacologic) activation of endogenous NSCs has been shown to enhance self-repair and recovery of function in the adult brain in both stroke [13,14] and neurodegeneration [15]. Importantly, NSCs and microglia relevantly interact with each other, thereby affecting their respective functions [16,17].

Thus, with the perspective of ar-turmerone as a therapeutic option in mind, we investigated the effects of ar-turmerone on NSCs in vitro and in vivo.

NSCs were cultured from fetal rat cortex at embryonic day 14.5, as described previously [18]. Cells were expanded as monolayer cultures in serum-free DMEM/F12 medium (Life Technologies, Darmstadt, Germany) with N2 supplement (Gibco, Karlsruhe, Germany) and fibroblast growth factor (FGF2; 10ng/ml; Invitrogen, Karlsruhe, Germany) for 5days and were replated in a 24-well plate at 10,000 cells per cm2. FGF2 was included throughout the experiments.

Ar-turmerone (Fluka, Munich, Germany) was added to cultures at replating at concentrations of 0, 1.56, 3.125, 6.25, 12.5, and 25g/ml. All experiments were performed in triplicate. After 72hours, representative pictures were taken by using an inverted fluorescence phase-contrast microscope (Keyence BZ-9000E). Three images were taken per well, and cells were counted by using the software ImageJ with a threshold of 20 px (National Institutes of Health, Bethesda, MD, USA, Version 1.47k).

Read this article:
Stem Cell Research & Therapy | Full text | Aromatic ...

Ryan Benton Discusses Stem Cell Therapy for Duchenne #39;s Muscular Dystrophy
Ryan Benton is the first patient in the United States to receive human umbilical cord-derived mesenchymal stem cell therapy for Duchenne #39;s muscular dystrophy. The US FDA granted Ryan this...

By: http://www.cellmedicine.com

Go here to read the rest:
Ryan Benton Discusses Stem Cell Therapy for Duchenne's Muscular Dystrophy - Video