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Kardiochirurgia i Torakochirurgia Polska/Polish Journal of Thoracic and Cardiovascular Surgery
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EXPERIMENTAL CARDIOVASCULAR AND LUNG RESEARCH
Biological effects of anti-CD34-coated ePTFE vascular grafts. Early in vivo experimental results

Wojciech Mrówczyński
,
Alessio Rungatscher
,
Franz Buchegger
,
Jean-Christophe Tille
,
Sophie Namy
,
Osman Ratib
,
Michael Kutryk
,
Beat Hans Walpoth

Kardiochirurgia i Torakochirurgia Polska 2014; 11 (2): 182-190
Online publish date: 2014/06/30
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Introduction

The use of expanded polytetrafluoroethylene (ePTFE) based materials is commonplace in contemporary medicine, especially for cardiovascular applications where there is a demand for biocompatible artificial vascular grafts. Although ePTFE vascular grafts provide excellent mechanical and handling properties, post-implant endothelialization is poor. This feature is crucial for small diameter grafts, particularly long grafts, in which the midportion of the prosthesis is rarely covered by native endothelial cells (ECs) [1]. Small diameter grafts that lack a healthy endothelial coverage are at risk of thrombotic occlusion, and, therefore, continuous anticoagulation is required. Intimal hyperplasia is the second major drawback of ePTFE prostheses that can potentially jeopardize their long-term patency. This phenomenon is again attributed to the absence of normal confluent endothelium and its microenvironmental influences that are responsible for the control of smooth muscle cell proliferation and migration.
Bone marrow-derived endothelial progenitor cells (EPCs) are a subset of circulating endothelial cells responsible for vascular and myocardial repair processes after injury and ischemia [2, 3]. These cells express the vascular endothelial growth factor receptor VEGFR-2, as well as the CD133 and CD34 antigens [3], and they possess great proliferative capacity. EPCs can form a functional endothelial lining on different polymers and have a positive influence on neointimal formation [4]. Thus, EPCs seem to be a promising means for neoendothelialization in tissue engineering and in the biofunctionalization of artificial vascular grafts including ePTFE prostheses.
As growing EPC tissue cultures can be time- and resource-consuming, a strategy was developed that relies on attracting and entrapping the circulating EPCs on the internal surface of the vascular graft. This is theoretically accomplished by an anti-CD34 antibody coating. This strategy has been proven to be feasible in experimental studies [5] as well as in the clinical application of anti-CD34-coated coronary artery stents [6-8]. The anti-CD34 coating can potentially accelerate uniform endothelialization, contributing to improving the patency of small caliber vascular grafts.
The aim of this study was to assess the biological activity of anti-CD34 antibody-coated ePTFE vascular prostheses and to verify the hypothesis of CD34 cell adhesion. The second aim was to verify whether different storage environments (aqueous or dehydrated) of the coated grafts influence their biological activity.

Material and methods

Animal preparation The experimental protocol was approved by the Animal Experiments Ethics Committee of the University of Geneva and the Veterinary Office of the State of Geneva (Switzerland; No. 10813271/3) and carried out in conformance with the Guide for the Care and Use of Laboratory Animals (National Research Council, Washington, D.C.: National Academy Press; 1996).
Five male Swiss Landrace pigs (mean weight: 41.3 kg, range: 39-45 kg) were premedicated with 3 mg/kg azaperone (Stresnil – Roche, Switzerland), anesthetized with 2% isoflurane (Isoflurane – Abbott, Switzerland), 4 mg pancuronium bromide (Pavulon – Organon, Switzerland), and 0.5 mcg/kg/min fentanyl (Fentanyl – Sintetica, Switzerland), and intubated. The animals were ventilated with a Servo Ventilator 900D respirator (Siemens, Germany) as well as monitored by the use of 3-lead ECG, SpO2, and direct arterial blood pressure measurement (AS/3 cardio-monitor – Datex, Finland). The animals were heparinized (10 000 IU) in order to obtain an ACT value of 2X baseline (Hemochrone, Datex). Additional heparin was administered in 200 IU increments if the target ACT was not achieved. After bilateral groin incisions, the femoral veins and arteries were identified, and 8F catheters were inserted using the Seldinger method. 37.5 ml of blood was withdrawn in 2.5 ml EDTA in order to harvest autologous thrombocytes that were consecutively labeled with indium111 (111In) and re-administered to animals. An arterio-venous (A-V) fistula was constructed and perfused according to the protocol described below. At the end of this acute experiment, all animals were sacrificed by potassium chloride overdose.

Preparation of autologous platelets

Porcine platelets were purified from whole blood containing citrate phosphate dextrose (CPD) solution (7 ml CPD/40 ml blood) by differential centrifugation initially at 200 x g for 15 minutes. The pellet containing sedimented white blood cells (WBC) and erythrocytes was discarded and CPD (10% v/v) was added to the platelet-containing supernatant and then centrifuged at 1000 x g for 10 min to yield sedimented platelets. Platelets were then labeled with 111In-Oxine (DRN 4908, Mallinckrodt Medical B.V., Le Petten, Netherlands) as previously described [9]. Sedimented platelets were briefly re-suspended in 3.0 ml NaCl (0.15 M) and 0.4 ml Tris buffer (Mallinckrodt Medical) and 1 ml 111In-Oxine solution and incubated for 20 min at 22°C. Platelet-poor plasma (PPP) was added in the amount of 0.6 ml, and the mixture was centrifuged at 1000 x g for 15 min, yielding radiolabelled platelets. Sedimented platelets, ready for use, were reconstituted in 3 ml of PPP. The activity of the sample was measured using a gamma-counter (Cobra II, Perkin-Elmer, MA, USA).

Anti-CD34-coated graft preparation

An ultrathin dextran coating was applied to the luminal surface of the commercially available ePTFE graft material (Bard Peripheral Vascular Inc., USA) using plasma technology. The surface was then functionalized, and CD34 antibody was covalently bound to the surface. The prepared grafts were then placed in saline solution containing 0.1% azide (wet grafts) or were lyophilized and exposed to 25 kGy γ radiation for sterilization (dry grafts). These two groups were included in order to assess the influence of storage conditions (lyophilized vs. aqueous solution) on the biological activity of the antibody.

The AV fistula

The ipsilateral femoral arterial and venous catheters were connected with one another by the random interposition of the vascular grafts to be assessed (diameter: 4 mm, length: 25 mm) – non-coated: A – dry ePTFE and C – wet ePTFE (Bard Peripheral Vascular Inc., USA), and coated: B – dry anti-CD34-coated ePTFE and D – wet anti-CD34-coated ePTFE (Orbus Neich, USA) joined by metallic connectors.
All the grafts were secured using ligatures encircling the prostheses around the connector. The dry grafts were connected to the circuit without pre-wetting. The wet grafts were rinsed generously with 0.9% saline before use. Blood pressure (AS/3 cardio-monitor – Datex, Finland) and flow through the fistula (MediStim, Oslo, Norway) were continuously monitored. The thrombocyte count of the pig as well as whole blood radioactivity were determined before and after each run of the circuit. The fistulas were perfused for 0, 10, 30, 60, and 120 minutes (bilateral fistulas were used: one for the 120 min cycle and a second one for the other cycles in order to minimize the time of the experimental procedure). Thus, each of the 4 graft types was perfused in 5 animals (n = 5) for 5 different periods. Consecutive runs of the fistula were performed in the following order: 120, 10, 30, and 60 min. After each fistula run, the grafts were removed, and both the arterial and venous arms were flushed with heparinized saline.

Specimen processing

After the end of each fistula cycle, all the vascular grafts were cut and rinsed with 50 ml of saline at 100 cm H20 pressure. The radioactivity of each sample was then measured by gamma counting (Cobra II, Perkin-Elmer, MA, USA) 1 and 2 hours after the experiment, showing minimal decay, as expected (p = ns). The first measurements were used for statistical analysis. All specimens were weighed, and radioactivity was expressed in counts per minute per milligram of the prosthesis for the purpose of normalization. After this assessment, all samples were fixed in 4% formaldehyde for 24 hours and then divided into two parts: for histology and scanning electron microscopy (SEM) studies.

Histology

For histological analysis, all 120 min perfusion samples were embedded in paraffin. Transverse histological sections (4 m) were stained with hematoxylin and eosin (H&E). The reason for performing histological and immunohistological studies on the grafts perfused for 120 min was twofold: as this was the first run of the fistula, it could potentially best reflect the early prosthesis-blood interaction without being biased by previous perfusions. Secondly, the first and longest perfusion time should maximize the likelihood of EPC entrapment on the lumen of the graft.
In order to characterize the cells adhering to the graft lumen, immunostaining was performed as follows: paraffin sections (4 µm) were deplasticized in warm xylene and ethanol, which was followed by their incubation in a graded series of alcohols and deionized water. Antigen retrieval was performed using heat, with the sections placed in Tris-EDTA buffer (pH 9.0). The slides were then placed in 3% H2O2 for 20 minutes, which was followed by blocking in horse serum and immunostaining using the following monoclonal anti-human antibodies: CD34 (dilution 1 : 25; Lifespan Biosciences, USA), CD62E/62P (dilution 1 : 10, Geneway, USA), CD31 (dilution 1 : 25, AbD SerotecUK), and CD133 (dilution 1 : 100; AbCam, USA) diluted in PBS (pH 7.5) at 4°C overnight. For the reaction with the secondary antibody and increased sensitivity, we used a Vectastain Elite ABC kit (Vector Labs Inc). Positive staining was visualized by a 3,3’diaminobenzidine (DAB) chromogen. The sections were counterstained with hematoxylin.
Pictures were taken at 100x and 200x magnification, using a Nikon Eclipse TS 100 microscope with a DS-Fi1 camera and a DS-L2 digital camera controller (Nikon, Japan) attached.
The slides were also analyzed quantitatively by computed histomorphometry with a motorized microscope (Nikon Eclipse 1, Japan) at 10x magnification and with image-processing software (ImageJ, US National Institutes of Health, 2010). The internal graft lumen area as well as intraluminal deposit area were measured.

Scanning electron microscopy

For SEM study, all samples were prepared with standard dehydration and gold coating techniques. A scanning electron microscope (Philips XL series, Netherlands) was utilized applying magnifications ranging from x100 to x1000. A semiquantitative specimen analysis was performed, taking into account the presence of separate cells, cell conglomerates, intraluminal deposits, and microthrombi.

Statistical analysis

The variables were expressed as medians and ranges. The normality of variable distribution was assessed by the Shapiro-Wilk test. The inter-group comparisons were performed using the Mann-Whitney U-test (A vs. B, C vs. D, A + C vs. B + D). A nonparametric Friedman ANOVA test was used for the intra-group repeated comparisons. Nonparametric Spearman correlations were performed to assess the relationship between sample activity and time. The investigators were not blinded to the nature of the different experimental grafts as storage methods were different.
A two-tailed p value of less than 0.05 was considered significant in all tests.

Results

AV fistula The animals’ platelet (PLT) counts measured before and after the AV shunt runs were diminishing, but the change was not significantly different – Table I. Whole blood activity changed insignificantly after each fistula run. The activity of each graft type during various perfusion times is presented in Figure 1. There was a significant difference between grafts A and B after 60 and 120 min of perfusion. The activities of grafts C and D were significantly different after 30, 60, and 120 min of AV fistula perfusion run duration. There were no significant differences between grafts B and D or between grafts A and C after all the AV fistula perfusion periods.
The activities of grafts B and D changed significantly over time (p = 0.003 and p = 0.012), while the values for grafts A and C remained constant (p = 0.061 and p = 0.072). The activities of grafts B and D correlated strongly with time of perfusion (respectively: r = 0.93 at p = 0.003 and r = 0.87 at p = 0.0001), whereas the results of grafts A and D showed only a weak relationship (r = 0.46 at p = 0.05 and r = 0.47 at p = 0.04).

Histology and planimetry

The results of the histological analyses are presented in Figure 2. After 120 min of perfusion, grafts A and C were characterized mainly by the presence of cells (granulocytes) adhering randomly to the inner surface of the graft. Acellular deposits (proteins, fibrin, and platelets) were not present or were extremely rare and occupied only a small part of the internal perimeter of the graft (not shown). Grafts B and D exhibited the presence of a thick layer of acellular deposits (proteins, fibrin, and platelets) accompanied by the presence of cells (granulocytes).
Immunostaining revealed no CD31+, CD62E/62P+, CD34+, or CD133+ cells in any grafts after 120 min of perfusion – Figure 3.
The median graft lumen area was similar (p = NS) in non-coated (A + C) and coated (B + D) grafts, amounting to, respectively, 17.8 mm2 (16.4-18.8) and 17.9 mm2 (17.2-18.1), which demonstrated that the antibody coating did not significantly influence the inner diameter of the graft. There was a significant difference in the areas of intraluminal deposits between the coated and non-coated grafts – Figure 4.

Scanning electron microscopy

All non-perfused grafts (0 min) had a similar ePTFE structure, showing no visible difference between coated and non-coated grafts. After 10 minutes of blood perfusion, single cells were present on the surface of coated grafts only. Thirty and 60 minutes of perfusion resulted in the presence of single cells on grafts A and C, while both coated grafts (B + D) were covered with acellular deposits accompanied by single and conglomerate cells, platelets, as well as microthrombi. Similar results were observed after 120 min in coated grafts, whereas graft A showed only the presence of single and conglomerate cells. Some acellular deposits were found on the internal lumen of graft C – Table II, Figure 5.

Discussion

This study shows that anti-CD34-coated ePTFE vascular grafts are able to bind significantly more porcine platelets and proteins than their non-coated equivalents. Both dry and wet coated grafts showed similar binding capacity, indicating no influence of different storage environments on the biological activity of the bound antibody. This is of fundamental importance with respect to the ease of preparation and longevity of storage in the case of dried/lyophilized implants. The process of lyophilization can change the conformation of the active epitopes of proteins, which may result in inactivation of the antibody [10]. The deposition of porcine platelets was assessed indirectly by measurement of the radioactivities of indium111-labelled PLTs adhering to the inner surface of the studied grafts. The presence of antigen CD34 on the surface of both human and porcine platelets has been described [11, 12]. The results of histological, planimetric, and SEM studies were in concordance with the quantitative radio-labeling assays. The non-coated grafts showed a significantly smaller area of intraluminal coverage in comparison to the anti-CD34-coated prostheses after 120 min of perfusion. The deposits on coated grafts consisted of platelets, fibrin, and nucleated cells (mainly neutrophils), which was also visible on SEM analysis. To our knowledge, this is the first report that describes the early phase of interaction between blood and an anti-CD34-coated vascular graft in an experimental setting.
The phenomenon described above can certainly raise some questions concerning the clinical applicability of a prosthesis that attracts PLTs and has the potential to induce thrombosis. However, this problem does not seem to be important in humans since no acute patency problems were reported with the use of anti-CD34-coated coronary artery stents [6-8]. Of course, the intensity of thrombocyte and fibrin deposition can also be attributed to the higher density of the anti-CD34 antibody, its higher absolute count, and finally its uniform spatial localization on the internal lumen of the ePTFE prosthesis in comparison to the minimal surface of anti-CD34-coated coronary artery stents.
Fibrin and platelet deposition may not necessarily be detrimental since animal experiments with anti-CD34-coated grafts, including this study, did not reveal frequent thrombotic events. In a chronic AV shunt pig model, Rotmans et al. found good patency of anti-CD34 antibody-coated grafts up to 28 days [5]. This may be related to the fact that CD34 is expressed on non-activated thrombocytes only [11]. Moreover, the experimental studies on mixed coating of adhesive polypeptide and anti-CD34 showed diminished aggregation of thrombocytes on such modified layers [13]. Platelet and fibrin depositions can also be advantageous as the prosthesis is immediately covered with the host’s own materials, mainly proteins, rendering it more biocompatible in comparison to a bare graft [14].
A second possible disadvantage of platelet and fibrin deposition is the blockade of prosthesis activity. As PLTs are more numerous in the circulation than EPCs, the active anti-CD34 antibodies may become saturated before the arrival of CD34-positive endothelial progenitor cells. However, this can also be favorable as initial platelet adhesion seems to be an essential step for the recruitment of progenitor cells to areas of vascular injury [14]. Therefore, the thrombocytes may act indirectly with fibrin deposits as mediators attracting EPCs to the surface of injured vessels or the coated ePTFE vascular graft material [14]. PLTs increase the migration and differentiation of ECs into mature cells and promote the colonization of EPCs [15].
It has already been questioned whether the CD34 antigen is the best marker for EPCs that could further differentiate into a functional EC layer. Thus, different strategies for EPC entrapment were developed including the use of the antibody against VEGFR-2, which seems to be a better indicator of endothelial potential [16]. In order to enhance the action of anti-CD34, which is a potential initiator of adhesion to the prosthetic wall, an adhesive polypeptide of mussel origin combined with the anti-CD34 antibody was used [13]. Other approaches have employed integrins with integrin-binding cyclic Arg-Gly-Asp peptides (cRDG), magnetic molecules, or single-stranded nucleic acids – aptamers [17]. This last method appears to be very promising due to the high affinity of aptamers to their target cells and the ease of their production, entirely by synthetic means. However, insufficiently characterized EPC markers as well as the heterogeneity of EPC populations make their adhesion very difficult.
Despite our use of four different antibodies during immunostaining studies, we were not able to detect the presence of cells possessing the characteristics of EPCs. There are several possible reasons for this failure. All specimens were formalin-fixed and paraffin-embedded, which could have had an impact on epitope structure. Moreover, the application of anti-human antibodies in a porcine model could have resulted in a false negative outcome despite in-vitro tests showing a cross-reactivity of about 60-70% between human antibodies and pig cells (personal communication of M. Kutryk). In fact, no signal from deposited thrombocytes could be detected either. In addition, due to a very small number of circulating EPCs, these cells may not have been visualized in our immunostaining studies because of the relatively large active surface of the AV shunt. Finally, a controversial explanation of EPCs’ absence in our immunostaining studies could be postulated in connection with the debate whether EPCs really exist and have a real role in biology [18, 19].

Study limitations

The cross-reaction between platelets and EPCs with the anti-CD34 antibody is certainly a limitation of this study as the CD34 antigens present on thrombocytes may rapidly saturate all the antibody active sites on the coverage of the prosthesis, preventing effective entrapment of relatively rare EPCs.
The in-vivo acute arterio-venous fistula setting is another potential limitation of the study as only an early phase (up to 2 hours) of prosthesis-host interaction is observed. The conditions of flow occurring in the extracorporeal AV shunt are not entirely physiological, which may influence the interaction between the prosthesis and blood as well as possibly activate leucocytes and thrombocytes. Similarly, the successive runs of the fistula circuit in the same animal could have certainly biased the results as the platelet and neutrophil activation could have occurred in the preceding sequence of the experiment.
A longer-term study with surgical implantation of the coated graft would likely provide better insight into the phenomenon of CD34-positive cell entrapment.
Finally, another important question is whether this model of early phase platelet-prosthesis interaction can be extrapolated to humans despite the fact that porcine thrombocytes react similarly to human PLTs in the presence of various biomaterials [20].

Conclusions

The anti-CD34-AB-coated grafts bind significantly more porcine proteins and platelets than uncoated prostheses in a time-dependent manner. The bioactivity of the antibody has been confirmed in complementary morphological studies and is not influenced by different graft storage environments. The coverage of the ePTFE graft by biological deposition may promote EPC adherence and differentiation into an endothelial cell layer. Thus, the anti-CD34 coating may enhance, directly or indirectly, the temporal and spatial endothelialization of vascular grafts and, thus, possibly improve clinical results. However, long-term animal studies are needed before its potential application in humans in order to confirm our hypothesis and study results of anti-CD34-coated vascular graft implantation.

Acknowledgements

We acknowledge Mrs. Lutzen and Mrs. Reymond for their help in histological and scanning electron microscope processing as well as Mrs. Ivana Kandic for performing the immunohistochemical staining. We would also like to express our gratitude to Mrs. Melodie Kaeser for her help in the correction of this manuscript.

Sources of funding/grants

Swiss National Science Foundation Grant #3100-56728. Samples provided free of charge by Orbus Neich.

Disclosures

Samples provided free of charge by Orbus Neich.

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Copyright: © 2014 Polish Society of Cardiothoracic Surgeons (Polskie Towarzystwo KardioTorakochirurgów) and the editors of the Polish Journal of Cardio-Thoracic Surgery (Kardiochirurgia i Torakochirurgia Polska). This is an Open Access article distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International (CC BY-NC-SA 4.0) License (http://creativecommons.org/licenses/by-nc-sa/4.0/), allowing third parties to copy and redistribute the material in any medium or format and to remix, transform, and build upon the material, provided the original work is properly cited and states its license.
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