Interventional stem cell therapy

Intra-Arterial Stem Cell Injection for Treating Various Diseases: A New Frontier in Interventional Radiology

This article provides radiologists with insights into stem cells' functions, sources, and potentially successful clinical treatments via intravascular injection in organs such as the liver, kidney, pancreas, musculoskeletal system, and for ischemic conditions affecting the brain, heart and limbs. Understanding stem cells' significance in interventional radiology and its limitations enables tailored interventions for diverse conditions, ensuring efficient medical care and optimal treatment selection.

Trans-Arterial Stem Cell Injection (TASI): The Role of Interventional Radiology in Regenerative Medicine

Regenerative medicine is taking a step forward in treating multiple diseases. The possibility of renewing damaged tissues with stem cells has become a topic of interest in recent decades. Still a relatively new research topic, many issues in this discipline are being addressed, from cell culturing to the study of different graft materials, and, moreover, cell delivery. For instance, direct intravenous injection has a big downfall regarding its lack of precision and poorly targeted treatment. Trans-arterial and direct percutaneous infusion to the aimed tissue/organ are both considered ideal for reaching the desired region but require image guidance to be performed safely and precisely. In this context, interventional radiology becomes pivotal for providing different cell delivery possibilities in every case. In this review, we analyze different basic stem cell therapy concepts and the current and future role of interventional radiology with a focus on trans-arterial delivery.

Image-Guided Transarterial Directed Delivery of Human Mesenchymal Stem Cells for Targeted Gastrointestinal Therapies in a Swine Model

PURPOSE

To evaluate the feasibility of catheter-directed intra-arterial stem cell delivery of human mesenchymal stem cells (MSCs) to the small bowel in a porcine model.

MATERIALS AND METHODS

The cranial mesenteric artery of 6 Yucatan minipigs was selectively catheterized under fluoroscopic guidance following cut-down and carotid artery access. A proximal jejunal branch artery was selectively catheterized for directed delivery of embolic microspheres (100-300 μm) or MSCs (0.1-10 million cells). The pigs were euthanized after 4 hours and specimens collected from the proximal duodenum and the targeted segment of the jejunum. The Chiu/Park system for scoring intestinal ischemia was used to compare hematoxylin and eosin-stained sections of jejunum and duodenum.

RESULTS

Successful delivery of microspheres or MSCs in a proximal jejunal branch artery of the cranial mesenteric artery was achieved in all subjects. Radiopaque microspheres and post-delivery angiographic evidence of stasis in the targeted vessels were observed on fluoroscopy after delivery of embolics. Preserved blood flow was observed after MSC delivery in the targeted vessel. The Chiu/Park score for intestinal ischemia in the targeted proximal jejunal segments were similar for microspheres (4, 4; n = 2) and MSCs (4, 4, 4, 3; n = 4), indicating moderate ischemic effects that were greater than for control duodenal tissue (3, 1; 0, 0, 3, 3).

CONCLUSIONS

Selective arteriographic deployment of MSCs in swine is feasible for study of directed intestinal stem cell delivery. In this study, directed therapy resulted in intestinal ischemia.

Characterisation and In Vivo Safety of Canine Adipose-Derived Stem Cells

The study characterises canine adipose-derived stem cells (cASCs) in comparison to human ASCs (hASCs) and tests their safety in a canine model after intravenous administration. cASCs from two dogs were cultured under hypoxic conditions in a medium supplemented with autologous serum. They were plastic adherent, spindle-shaped cells that expressed CD73, CD90, and CD44 but lacked CD45, CD14, HLA-DR, and CD34. cASCs differentiated toward adipogenic, osteogenic, and chondrogenic lineages, although adipogenic differentiation capacity was low. Blast transformation reaction demonstrated that these cells significantly suppress T-cell proliferation, and this ability is dose-dependent. Intravenous administration of a cell freezing medium, therapeutic dose of cASCs (2 × 106 live cells/kg), and five times higher dose of cASCs showed no significant side effects in two dogs. Microscopic tissue lesions were limited to only mild, non-specific changes. There were no signs of malignancy. The results of the study indicate that cASCs are similar to hASCs and are safe for therapeutic applications in a canine model. The proposed methodology for ASC preparation on a non-routine basis, which includes individually optimised cell culture conditions and offers risk-adapted treatment, could be used for future personalised off-the-shelf therapies, for example, in myocardial infarction or stroke.