Cellular cardiomyoplasty : optimizing cellular dosage and retention by microencapsulation

Al Kindi, Adil Hashim, 1976-

January 2008

Cellular Cardiomyoplasty (cell therapy for myocardial regeneration) targets the basic pathophysiology of heart failure and represents a novel technique for augmenting the function of the failing heart. Previous studies have demonstrated massive mechanical losses in the first few minutes. Thus, efforts to reduce mechanical losses may prove more beneficial than those directed against biological losses alone. We believe that "Wash-out" into the disrupted blood vessels is responsible for these early losses. / In the first part of this study we hypothesized that by increasing the size of the injectate, the amount of immediate losses can be reduced achieving better retention. Using Alginate-poly-L-lysine-Alginate (APA) miscrocapsules of two different sizes (200mum&400mum) and comparing retention with bare microspheres (10mum) of similar size to MSCs, we demonstrated that immediate retention rate increased by four folds. The retention rate for group 1 (microspheres only) was 4.28+/-3.46% which was significantly lower than that for groups 2 (microspheres in 200mum microcapsules) at 16.45+/-12.66% and group 3 (microspheres in 400mum microcapsules) at 12.93+/-6.28% for Group (p<0.05). There was no difference between group 2 and 3. / In the second part, we investigated the potential of gradually increasing the cell load on functional improvement and engraftment using conventional intramuscular delivery. Five groups of rats received escalating doses of MSCs after surgically induced ischemia (gp1 no cells, gp2 0.5x 10 6, gp3 1.5x106, gp4 3x106,gp5 5x106 MSCs). At 7 weeks, we observed significant improvement in cardiac function in groups 3 to 5 compared to post-infarction baseline. This was not observed in groups 1 & 2. However, in groups 3 to 5, we observed no functional advantage for increasing the cell load beyond a minimal therapeutic dose. This is consistent with our hypothesis that small cells are washed out into the circulation. / We also showed the ability of Alginate-Poly-l-lysine-Alginate (APA) microcapsules to sustain the viability of encapsulated MSCs in-vitro. Finally, the ability of encapsulated MSCs to improve the function of the heart in-vivo was tested.

Myocardial Infarction -- surgery.

Myocardium -- cytology.

Stem Cell Transplantation -- methods.

Rats.

Cellular cardiomyoplasty : optimizing cellular dosage and retention by microencapsulation

Al Kindi, Adil Hashim

January 2008

No description available.

Myocardial Infarction -- surgery.

Stem Cell Transplantation -- methods.

Myocardium -- cytology.

Rats.

Dexamethasone Stimulates Release of an ANP-Like Substance From Rainbow Trout Cardiocytes

Powell, W. H., Miller, Hugh A.

01 August 1992

A substance that cross-reacts with antiserum to human atrial natriuretic peptide (ANP) is found in fish hearts. This ANP-like material increases sodium output from the gill and kidney while inhibiting sodium uptake in the gut. Mammalian ANP secretion is stimulated by glucocorticoids, and cortisol injection increases sodium output in salt-loaded fish. Therefore, we wanted to determine if the release of ANP in fish is sensitive to dexamethasone. Ventricle cardiocytes from the rainbow trout Oncorhynchus mykiss were treated with various doses of dexamethasone for 18 or 72 h. Single ventricle cells were then assayed for ANP release using a reverse hemolytic plaque assay and antiserum to human alpha-ANP. Incubation with 100 microM dexamethasone almost doubled the population of ventricle cells committed to ANP release (basal, 15.0 +/- 0.3% vs. Dexamethasone, 28.3 +/- 1.4%; values are percent plaque formation +/- SE). Stimulation of ANP secretion was dependent on dose and time of exposure to dexamethasone. These results suggest that ANP secretion in fish is regulated by glucocorticoids.

animals

atrial natriuretic factor (metabolism)

dexamethasone (pharmacology)

hemolytic plaque technique

myocardium (cytology

metabolism)

time factors

trout (metabolism)

Biological Sciences