New Murine Model of Spontaneous Autologous Tissue Engineering, Combining an Arteriovenous Pedicle with Matrix Materials

Cronin, Kevin; Messina, Aurora; Knight, Kenneth R.; Cooper-White, Justin J.; Stevens, Geoffrey W.; Penington, Anthony; Morrison, Wayne A.

doi:10.1097/01.prs.0000095942.71618.9d

Cited by 137 publications

(134 citation statements)

References 23 publications

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“…23 Here the cells grow in parallel with the newly developing capillary bed to form a vascularized interconnected network of cardiac tissue. We have previously shown in both rat 21 and mouse 38 chambers that other implanted tissues and cells, such as muscle, 17 myoblasts, 17 fat, 39 pancreatic islets, 40 fetal tissue, and fibroblasts, 16 can survive with this methodology. By seeding cardiomyocytes into a chamber in the rat, we have grown a living piece of cardiac tissue with a volume of Ϸ0.2 mL and thickness up to 1983 m, which easily exceeds the dimensions expected to be supported by diffusion alone (Figure 6).…”

Section: Discussionmentioning

confidence: 99%

Cardiac Tissue Engineering in an In Vivo Vascularized Chamber

et al. 2007

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Background— Cardiac tissue engineering offers the prospect of a novel treatment for acquired or congenital heart defects. We have created vascularized pieces of beating cardiac muscle in the rat that are as thick as the adult rat right ventricle wall. Method and Results— Neonatal rat cardiomyocytes in Matrigel were implanted with an arteriovenous blood vessel loop into a 0.5-mL patented tissue-engineering chamber, located subcutaneously in the groin. Chambers were harvested 1, 4, and 10 weeks after insertion. At 4 and 10 weeks, all constructs that grew in the chambers contracted spontaneously. Immunostaining for α-sarcomeric actin, troponin, and desmin showed that differentiated cardiomyocytes present in tissue at all time points formed a network of interconnected cells within a collagenous extracellular matrix. Constructs at 4 and 10 weeks were extensively vascularized. The maximum thickness of cardiac tissue generated was 1983 μm. Cardiomyocytes increased in size from 1 to 10 weeks and were positive for the proliferation markers Ki67 and PCNA. Connexin-43 stain indicated that gap junctions were present between cardiomyocytes at 4 and 10 weeks. Echocardiograms performed between 4 and 10 weeks showed that the tissue construct contracted spontaneously in vivo. In vitro organ bath experiments showed a typical cardiac muscle length-tension relationship, the ability to be paced from electrical field pulses up to 3 Hz, positive chronotropy to norepinephrine, and positive inotropy in response to calcium. Conclusion— In summary, the use of a vascularized tissue-engineering chamber allowed generation of a spontaneously beating 3-dimensional mass of cardiac tissue from neonatal rat cardiomyocytes. Further development of this vascularized model will increase the potential of cardiac tissue engineering to provide suitable replacement tissues for acquired and congenital defects.

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Section: Discussionmentioning

confidence: 99%

Cardiac Tissue Engineering in an In Vivo Vascularized Chamber

et al. 2007

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“…Cylindrical silicone chambers, 5 mm long, 3.35 mm internal diameter, 44 l volume (Dow-Corning Corp., Midland, MI) were placed on the right epigastric pedicle according to a method modified from Cronin and colleagues 22 ( Figure 1, a-d). The right superficial epigastric vessels were dissected free of surrounding tissue from their origin at the femoral vessels to their insertion into the groin fat pad.…”

Section: Surgical Techniquesmentioning

confidence: 99%

Angiogenic Growth Factor Synergism in a Murine Tissue Engineering Model of Angiogenesis and Adipogenesis

Rophael

Craft

Palmer

et al. 2007

The American Journal of Pathology

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De novo tissue generation stimulated by three angiogenic growth factors administered in a factorial design was studied in an in vivo murine tissue engineering chamber. A silicone chamber was implanted around the epigastric pedicle and filled with Matrigel with 100 ng/ml of recombinant mouse vascular endothelial growth factor-120 (VEGF 120 ), recombinant human basic fibroblastic growth factor (FGF-2), or recombinant rat platelet-derived growth factor-BB (PDGF-BB) added as single, double, or triple combinations. Angiogenesis, supporting tissue ingrowth, and adipogenesis were assessed at 2 and 6 weeks by immunohistochemistry and morphometry. At 2 weeks angiogenesis was synergistically enhanced by VEGF 120 ؉ FGF-2 (P ‫؍‬ 0.019). FGF-2 (P ‫؍‬ 0.008) and PDGF-BB (P ‫؍‬ 0.01) significantly increased connective tissue/inflammatory cell infiltrate (macrophages, pericytes, and preadipocytes) in double and triple combinations compared with control. At 6 weeks sequential addition of growth factors increased the percent volume of adipose tissue (P < 0.0005, each main effect), with a synergistic increase in adipose tissue in combination treatments (P < 0.0005). Groups containing 300 ng/ml of single growth factors produced significantly less adipose tissue than the triple growth factor combination (P < 0.0005, VEGF 120 and PDGF-BB; P < 0.001, FGF-2). In conclusion, angiogenic growth factor combinations increased early angiogenesis and cell infiltration resulting in synergistically increased adipose tissue growth at 6 weeks. Two way and higher level synergies are likely to be important in therapeutic applications of angiogenic growth factors.

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“…[3][4][5][6] We have developed a murine tissue engineering model that comprises a silicon chamber enclosing the superficial epigastric vascular pedicle in a Matrigel environment. The chamber has been used in several formats, closed, 7 partially closed 8 , and in a delayed seeding model. 9 We have demonstrated that new vascularized tissue forms in the chamber 7 and that an open chamber, allowing contact with surrounding tissue, improves adipogenesis.…”

Section: Introductionmentioning

confidence: 99%

Macrophages Play a Key Role in Angiogenesis and Adipogenesis in a Mouse Tissue Engineering Model

Debels

Galea

Han

et al. 2013

Tissue Engineering Part A

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We have previously described a mouse adipose tissue engineering model using a silicon chamber enclosing the superficial epigastric pedicle in a Matrigel based environment. We have shown that when Zymosan, a sterile inflammatory agent, is added to the chamber, angiogenesis and adipogenesis are significantly improved. As Zymosan interacts with toll-like receptors on macrophages, the role of macrophages in new tissue development in the tissue engineering chamber was assessed. Morphological and histological results showed that macrophages were presenting in high numbers at 2 weeks but had decreased significantly by 4 and 6 weeks in the chamber. Numerous immature new blood vessels had formed by 2 weeks, becoming more mature at 4 and 6 weeks. Immature adipocytes were visualized at 4 weeks and mature cells, at 6 weeks. To investigate the functional role of macrophages in the tissue engineering process, we knocked out the local macrophage population by inserting Clodronate liposomes in this chamber. This study shows for the first time that when macrophages are depleted, there is minimal new vascular and adipose tissue development. We propose a new theory for tissue engineering in which macrophages play a central role in both neovascularisation and adipogenesis.

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New Murine Model of Spontaneous Autologous Tissue Engineering, Combining an Arteriovenous Pedicle with Matrix Materials

Cited by 137 publications

References 23 publications

Cardiac Tissue Engineering in an In Vivo Vascularized Chamber

Cardiac Tissue Engineering in an In Vivo Vascularized Chamber

Angiogenic Growth Factor Synergism in a Murine Tissue Engineering Model of Angiogenesis and Adipogenesis

Macrophages Play a Key Role in Angiogenesis and Adipogenesis in a Mouse Tissue Engineering Model

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