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עמוד בית
Sun, 24.11.24

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December 2020
Tiberiu R. Shulimzon MD, Shir Giladi BSc, and Meital Zilberman PhD

Background: Chronic lung diseases, especially emphysema and pulmonary fibrosis, are the third leading cause of mortality worldwide. Their treatment includes symptom alleviation, slowing of the disease progression, and ultimately organ transplant. Regenerative medicine represents an attractive alternative.

Objectives: To develop a dual approach to lung therapy by engineering a platform dedicated to both remodeling pulmonary architecture (bronchoscopic lung volume reduction) and regeneration of lost respiratory tissue (scaffold).

Methods: The authors developed a hydrogel scaffold based on the natural polymers gelatin and alginate. The unique physical properties allow its injection through long catheters that pass through the working channel of a bronchoscope. The scaffold might reach the diseased area; thus, serving a dual purpose: remodeling the lung architecture as a lung volume reduction material and developing a platform for tissue regeneration to allow for cell or organoid implant.

Results: The authors’ novel hydrogel scaffold can be injected through long catheters, exhibiting the physical and mechanical properties necessary for the dual treatment objectives. Its biocompatibility was analyzed on human fibroblasts and mouse mesenchymal cells. Cells injected with the scaffold through long narrow catheters exhibited at least 70% viability up to 7 days.

Conclusions: The catheter-injectable gelatin-alginate hydrogel represents a new concept, which combines tissue engineering with minimal invasive procedure. It is an inexpensive and convenient to use alternative to other types of suggested scaffolds for lung tissue engineering. This novel concept may be used for additional clinical applications in regenerative medicine.

July 2016
Guy Witberg MD, Ifat Lavi PhD, Hana Vaknin Assa MD, Katia Orvin MD, Abid Assali MD and Ran Kornowski MD FESC FACC

Background: Bioresorbable vascular scaffold (BVS) is a promising technology that potentially offers several advantages over contemporary coronary drug-eluting stents (DES). Crucial to BVS implantation is the correct choice of scaffold size (diameter and length) in order to avoid "geographic miss" in length, provide the maximal support to the vessel wall, and avoid leaving “free-floating” foreign material in the coronary vasculature. 

Objectives: To assess the optimal method for measuring coronary stenosis prior to BVS implantation.

Methods: We compared the performance of two quantitative coronary angiography assessment (QCA) techniques: two dimensional real-time QCA (2D-QCA) and offline 3D QCA (3D-QCA) for the evaluation of coronary lesions in patients enrolled in a multicenter randomized controlled trial of BVS vs. metallic stents, by calculating the weighted kappa value for agreement regarding optimal BVS size with the reference method – CoreLab offline 2D-QCA measurements..In addition, we collected 2 year clinical outcomes (death/myocardial infarction/repeat revascularization/scaffold thrombosis) in BVS-implanted patients.

Results: In 17 patients with available CoreLab data, the weighted kappa for agreement for 3D-QCA was significantly better than for 2D-QCA (0.90, 95%CI 0.72–1.00 vs. 0.439, 95%CI 0.16–0.77). The rate of clinical events at 2 years was low (9.5%).

Conclusions: Initial experience in a small group of carefully selected patients at our institution, suggests that the use of BVS for coronary revascularization is associated with a low rate of adverse events in suitable patients. 3D-QCA may be superior to 2D-QCA analysis in terms of reproducibility, and results in more patients receiving optimal size BVS. 

 

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