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Ann Thorac Surg 1996;62:1724-1730
© 1996 The Society of Thoracic Surgeons

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Original Articles: Cardiovascular

No-React Detoxification Process: A Superior Anticalcification Method for Bioprostheses

Section of Cardiothoracic Surgery, UMDNJ-New Jersey Medical School, Departments of Surgery and Preventive Medicine and Community Health, Newark, New Jersey

	Abstract

Top Footnotes Abstract Introduction Material and Methods Results Comment References

 
Background. Glutaraldehyde pretreatment of bioprosthetic heart valves is the major pathogenic factor in their calcific degeneration. This comparative study investigates the merit of the No-React aldehyde detoxification process as an alternative modifier of xenograft tissues.

Methods. Glutaraldehyde- and No-React-pretreated porcine aortic valve cusps were implanted subcutaneously in 6-week-old rats (n = 20). At 3, 6, and 14 weeks, randomly selected animals were sacrificed and the explants underwent mineral and morphologic analyses. Glutaraldehyde- and No-React-treated bovine pericardium and porcine aortic valve cusp were incubated in fibroblast cell culture plates. Cell viability was observed under reversed microscope at 6, 24, 48, and 96 hours. Erythrosin B dye exclusion test was used to validate percent cell death.

Results. Pretreatment with No-React significantly inhibited calcification of aortic cusp subcutaneous implants throughout the 14-week period (mean tissue Ca²⁺ content = 1.3 ± 0.7 µg/mg at 14 weeks.) Glutaraldehyde-treated cusps underwent protracted calcification (Ca²⁺ content = 190.6 ± 89.5 µg/mg; p < 0.01). Morphologic findings correlated with mineral analyses. One-hundred percent of fibroblast cells survived in the presence of No-React-treated tissue, with a growth pattern indistinguishable from control cell culture (ie, in the presence of no tissue). The cells incubated with glutaraldehyde-treated tissue showed signs of nonviability by 6 hours, with 100% cell death by 48 hours. Dye exclusion tests validated these findings.

Conclusions. The No-React detoxification process completely abolishes the cytotoxicity of the xenograft tissue and inhibits calcific degeneration.

	Introduction

Top Footnotes Abstract Introduction Material and Methods Results Comment References

 
See also page 1730.

The search for a durable bioprosthetic heart valve has been a focus of intense investigation for the past two decades. Biological valve prostheses display superior hemodynamics and low thrombogenicity [1]. The relative simplicity of insertion and reported reduced incidence of thromboembolism are among the other advantages of the biological valve prosthesis over mechanical valves [1]. However, the major factor limiting clinical use of the commercially available glutaraldehyde (GTA)-pretreated bioprosthetic valves is their late structural deterioration, most commonly as a result of calcific mineralization and degeneration. Reoperation, and its associated morbidity and mortality, is the eventual outcome in approximately 20% to 30% of the bioprosthetic valve recipients by the tenth postoperative year [1, 2]. Moreover, several retrospective clinical reports have described accelerated tissue valve calcification and earlier functional failure in young adults and children, condemning biological valve implantation in these groups of patients [3–5]. Glutaraldehyde is currently the standard reagent for preservation and biochemical fixation of fresh bioprosthetics of either bovine pericardium or porcine aortic valve cusp origin. Multiple studies have implicated the aldehyde-induced collagen cross-linkages and devitalization of the intrinsic connective tissue cells of the bioprosthetic valves in initiating tissue mineralization [2, 6–8]. The cytotoxicity of GTA has been detected in animal tissues as long as 6 months after implantation [9]. Furthermore, alarmingly, GTA has been traced in human porcine valve explants up to 14 years after implantation [10].

Since the introduction of the No-React (NR) biochemical modification method by Biocor, Belo Horizonte, Brazil, our laboratory has engaged in delineating the merits of this aldehyde detoxification process in preventing xenograft dystrophic calcification. Previous studies in our laboratory have demonstrated comparable in vitro tensile strength of the NR-processed heart valve bioprostheses [11, 12]. Moreover, we have described antiinflammatory and anticalcification properties of the NR on bovine pericardial subcutaneous implants [13]. We have observed severe foreign body reaction in the form of giant cell infiltration in GTA-pretreated pericardial implants, a response completely abrogated by NR pretreatment. These findings were suggestive of a correlation between the inflammatory destruction of the tissue implant and the pericardial calcification. The present study illustrates our longitudinal observations on the trend of mineralization of subcutaneously implanted porcine aortic valve cusps pretreated with GTA versus NR. Furthermore, it examines the dichotomous results of extensive cytocompatibility testing of GTA-treated versus NR-treated xenografts, and investigates the potential correlation between xenograft tissue cytocompatibility and calcific mineralization.

	Material and Methods

Top Footnotes Abstract Introduction Material and Methods Results Comment References

 
In Vivo Calcification Studies
SUBCUTANEOUS IMPLANTATION.
Twenty Sprague-Dawley rats (SD strain; Taconic Laboratories, German Town, NY), 6 weeks old (80 to 100 g), were used. On day 0, all animals received GTA- and NR-pretreated porcine aortic valve cusp implants in separate subcutaneous pouches in the anterior abdominal wall. All procedures were performed under sterile conditions after intraperitoneal pentobarbital injections. The wounds were closed with 5-0 Vicryl (Ethicon, Somerville, NJ) suture material. The rats were fed Lab Rodent Diet (Purina Meals Inc, St. Louis, MO) and received humane care in compliance with the "Principles of Laboratory Animal Care" formulated by the National Society for Medical Research and the "Guide for The Care and Use of Laboratory Animals" prepared by the Institute of Laboratory Animal Resources and published by National Institutes of Health (NIH publication 86-23, revised 1985). At 3, 6, and 14 weeks after implantation, randomly selected animals were sacrificed with a lethal intraperitoneal dose of thiopental (300 mg/kg) and the tissue specimens were retrieved. A small portion of each specimen was immediately fixed in 10% neutral buffered formalin for light microscopic examination. The remainder of each sample underwent mineral analysis.

MINERAL ANALYSES.
Aortic cusp explants were washed with sterile saline solution and dried to constant weight in a 90°C desiccator oven. Tissue concentrations of calcium was determined by previously described techniques [14] using flame atomic absorption spectrophotometry (Perkin-Elmer model 603; Perkin-Elmer, Norwalk, CT) after digestion with a 3:1 mixture of 70% nitric and perchloric acids (GFS Chemicals, Columbus, OH). National Institutes of Standards and Technology bovine liver (SRM 1577a; Gaithersburg, MD) was used as a quality control sample for all analyses. Concentrations were expressed as micrograms per milligram of dry tissue weight (mean ± standard deviation).

MORPHOLOGIC ANALYSES.
Sample fragments removed for histologic evaluation were fixed immediately in 10% neutral buffered formalin, dehydrated in graded concentrations of ethanol, cleared in xylene, and embedded in paraffin according to standard methods. Sections 5 µm thick were stained by hematoxylin and eosin and von Kossa stain.

Cytocompatibility Studies
CELL CULTURE.
The cell line used was L-929 mouse fibroblast cell line obtained from the American Type Culture Collection (Rockville, MD). The cryovial of cells was immersed in oscillating 37°C water bath within 1 to 1.5 minutes. The cell suspension was then sterilely transferred to a 75-cm² culture flask containing preequilibrated and prewarmed Dulbecco's modified Eagle medium (pH = 7.30), supplemented with penicillin (100 IU/mL), streptomycin (100 µg/mL), amphotericin B (2.5 µg/mL), fetal bovine serum (10%), and nonessential amino acids (1%) (BRL, Grand Island, NY). The culture flask was incubated in 37°C humidified incubator with 5% CO₂ concentration in air. After 72 hours, the confluent cells were subcultured at approximately 40,000 cells/cm² in 12-well dishes (Falcon, Becton Dickenson, NJ) and allowed to grow to a monolayer of cells before introduction of tissue samples.

CYTOCOMPATIBILITY TEST.
Glutaraldehyde- and NR-pretreated tissue segments were cut into 3 x 3-mm strips under sterile conditions. The strips were washed in three serial changes of sterile phosphate-buffered saline solution (pH = 7.3) and individually introduced into the cell culture wells. The wells were then supplemented with fresh medium. At 6, 24, 48, or 96 hours after incubation, the cells were examined under a reversed light microscope. One cell culture dish containing no tissue was assigned as a control in each set of experiments.

DYE EXCLUSION METHOD.
Six, 24, and 48 hours after tissue incubation, 0.5 mL of 0.06% erythrocin B solution was added to each cell culture well, dwelled for 30 seconds, and then withdrawn. The dyed cells immediately adjacent to the tissue were counted under bright-field reversed microscopy. The rationale for this technique is that viable cells are impermeable to dye (erythrosin B; Sigma, St. Louis, MO). On the other hand, the dye leaks into those cells that have sustained critical damage to their plasma membrane. The ratio of stained cells to total cells counted (x100) estimates the percent cell death. (Note: it is important to bear in mind that this method can overestimate viability, as other forms of cellular injury progressing to cell death are undetected.)

Statistical Methods
Tissue calcium content were compared for differences between GTA- and NR-pretreated tissues using two-tailed independent Student's t test. Percent cell viability (discontinuous data) were evaluated by ² analysis using the Fisher exact test. Statistical significance was declared at p less than 0.05.

	Results

Top Footnotes Abstract Introduction Material and Methods Results Comment References

 
Subcutaneous Implants
One animal died in the immediate postoperative period of anesthesia overdose. The results of mineral analyses of the GTA- versus NR-pretreated porcine aortic valve cusps after 3, 6, and 14 weeks of subcutaneous implantation are summarized in Figure 1. Glutaraldehyde-treated cusps showed progressive unremitting calcification over the time span of the experiment with mean tissue calcium content increasing from 72.0 ± 40.5 µg/mg at 3 weeks to 190.6 ± 89.5 µg/mg at 14 weeks. No-React--treated cusp mineralization remained negligible even after 14 weeks of subcutaneous implantation (p < 0.01 versus GTA control).

View larger version (30K): [in this window] [in a new window]   Fig 1. . Trend of calcification of subcutaneous porcine cusp implants over a 14-week period. The glutaraldehyde-treated cusps show a progressive calcification over time. The No-React--treated cusps undergo minimal calcification with no progression over time (p < 0.01).

View larger version (127K): [in this window] [in a new window]   Fig 2. . Light photomicrographs of glutaraldehyde-treated cusp explants at 6 weeks. (A) Disruption of the collagen fibrils and inflammatory reaction (hematoxylin and eosin). (B) A glutaraldehyde-treated cusp stained with von Kossa stain; calcium deposits are seen as black spots. (C) Higher magnification of an aortic cusp explant showing severe inflammatory cell infiltration. (D) Higher magnification of B hematoxylin and eosin. (Magnifications: A, x100; B, x100; C, x200; D, x200.)

View larger version (120K): [in this window] [in a new window]   Fig 3. . Light photomicrographs of No-React--treated cusp explants at 6 weeks. (A) Collagen matrix of the cusp is preserved; no inflammatory reaction is seen (hematoxylin and eosin). (B) Same cusp stained with von Kossa stain; no calcium deposits are seen. (C) Higher magnification of No-React--treated cusp explant with well-preserved architecture (hematoxylin and eosin). (D) Von Kossa stain of the cusp in slide C. (Magnifications: A, x100; B, x100; C, x200; D, x200.)

View larger version (85K): [in this window] [in a new window]   Fig 4. . Reverse light photomicrographs of cell culture plates incubated with pericardial tissue at time 0. (A) No-React--treated tissue (Ts) at the bottom of the figure; live mature fibroblasts at the top of the figure. (B) Glutaraldehyde-treated Ts at the bottom; live fibroblasts at the top.

View larger version (119K): [in this window] [in a new window]   Fig 6. . Erythrosin B dye exclusion test observed at 48 hours. (A) The fibroblasts form a confluent monolayer around the No-React--treated tissue (Ts). (B) Near 100% cell death with glutaraldehyde-treated Ts incubation.

View larger version (30K): [in this window] [in a new window]   Fig 7. . Dye exclusion test: comparison of dead cell count between the No-React-- and glutaraldehyde--treated tissues.

	Comment

Top Footnotes Abstract Introduction Material and Methods Results Comment References

No-React xenograft pretreatment involves (1) aldehyde cross-linkage to achieve high resistance to biodegradation, (2) an aldehyde detoxification process, and (3) surface modification with a surfactant. The results of the present study illustrate the superior biological properties of the NR biochemical modification process, the attributes that we believe are fundamental to formulation of an acceptable bioprosthetic tissue preparation method. These properties are as follows: (1) No-React pretreatment maintains intrinsic collagen architecture and structural integrity of both bovine pericardium and porcine aortic valve cusp in an in vivo environment. (2) No-React aldehyde detoxification process inhibits crystal enucleation on the xenograft tissue, in what we have observed as a near-complete abolishment of calcific mineralization of the implants to a degree indistinguishable from historical untreated tissue implants. (3) The remarkably inert nature of surfactant-protected NR-treated tissue supports coexistence and normal growth of connective tissue cells, illustrating optimal cytocompatibility. In other words, the NR biochemical modification process efficiently protects the components of the xenograft tissue that are subject to calcific deposition, namely collagen and connective tissue cells. We have also shown that conventional GTA is a clearly inferior tissue-preparative modality. Glutaraldehyde has toxic effects on both extracellular and cellular elements of bioprosthetic xenograft, inevitably leading to calcific degeneration.

Given these preclinical findings and the encouraging early results of the ongoing clinical investigations on the use of NR-treated biological implants [16, 17], we foresee the future era of the biological heart valve implantation to involve exclusive insertion of detoxified tissue valves with superior long-term durability in a wider spectrum of recipients.

View larger version (119K): [in this window] [in a new window]   Fig 5. . Reverse light photomicrographs of cell culture plates at 6 and 24 hours after tissue incubation, with addition of erythrosin B to the medium. (A) Healthy dividing cells adjacent to No-React tissue (Ts) at 6 hours. (B) Cells begin to acquire red stain (black round figures) 6 hours after incubation with glutaraldehyde-treated Ts. (C) At 24 hours, 100% of the cells are viable in presence of No-React--treated tissue. (D) At 24 hours, progressive loss of viability of the cells incubated with glutaraldehyde-treated tissue is notable, as evident in the entire field.

	Footnotes

Top Footnotes Abstract Introduction Material and Methods Results Comment References

Address reprint requests to Dr Gabbay, UMDNJ-New Jersey Medical School, 185 South Orange Ave, Rm G-502, Newark, NJ 07103.

	References

Top Footnotes Abstract Introduction Material and Methods Results Comment References

 

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This Article Abstract Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Add to Personal Folders Download to citation manager Author home page(s): Amir Abolhoda Keith R. Allen Qi Lu Shlomo Gabbay Permission Requests Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Abolhoda, A. Articles by Gabbay, S. Search for Related Content PubMed PubMed Citation Articles by Abolhoda, A. Articles by Gabbay, S. Related Collections Related Article