Molecular assessment of collagen denaturation in decellularized tissues using a collagen hybridizing peptide.

Decellularized extracellular matrix (ECM) derived from tissues and organs are emerging as important scaffold materials for regenerative medicine. Many believe that preservation of the native ECM structure during decellularization is highly desirable. However, because effective techniques to assess the structural damage in ECM are lacking, the disruptive effects of a decellularization method and the impact of the associated structural damage upon the scaffold's regenerative capacity are often debated. Using a novel collagen hybridizing peptide (CHP) that specifically binds to unfolded collagen chains, we investigated the molecular denaturation of collagen in the ECM decellularized by four commonly used cell-removing detergents: sodium dodecyl sulfate (SDS), 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (CHAPS), sodium deoxycholate (SD), and Triton X-100. Staining of the detergent-treated porcine ligament and urinary bladder matrix with carboxyfluorescein-labeled CHP demonstrated that SDS and Triton X-100 denature the triple helical collagen molecule while CHAPS and SD do not, although second harmonic generation imaging and transmission electron microscopy (TEM) revealed that all four detergents disrupt collagen fibrils. Our findings from the CHP staining were further confirmed by the circular dichroism spectra of intact triple helical collagen molecules in CHAPS and SD solutions, and the TEM images of CHP-conjugated gold nanoparticles binding only to the SDS and Triton X-100 treated collagen fibrils. CHP is a powerful new tool for direct and reliable measurement of denatured collagen molecules in decellularized tissues. It is expected to have wide applications in the development and standardization of the tissue/organ decellularization technology. Preservation of the native ECM structure in decellularized tissues is highly desirable, since denaturation of ECM molecules (e.g., collagen) during decellularization can strongly influence the cellular response. Unfortunately, conventional techniques (SEM, SHG) are not conducive to identifying denatured collagen molecules in tissues. We demonstrate the first investigation into the molecular denaturation of collagen in decellularized ECM enabled by a novel Collagen Hybridizing Peptide (CHP) that specifically binds to unfolded collagen chains. We show that SDS and Triton X-100 denature collagen molecules while CHAPS and SD cannot. Such detection has been nearly impossible with other existing techniques. The CHP technique will advance our understanding about the effect of the cell-removing process on ECM, and lead to development of the decellularization technology.

Hwang J ，San BH ，Turner NJ ，White LJ ，Faulk DM ，Badylak SF ，Li Y ，Yu SM ... -  《-》

The impact of detergents on the tissue decellularization process: A ToF-SIMS study.

Biologic scaffolds are derived from mammalian tissues, which must be decellularized to remove cellular antigens that would otherwise incite an adverse immune response. Although widely used clinically, the optimum balance between cell removal and the disruption of matrix architecture and surface ligand landscape remains a considerable challenge. Here we describe the use of time of flight secondary ion mass spectroscopy (ToF-SIMS) to provide sensitive, molecular specific, localized analysis of detergent decellularized biologic scaffolds. We detected residual detergent fragments, specifically from Triton X-100, sodium deoxycholate and sodium dodecyl sulphate (SDS) in decellularized scaffolds; increased SDS concentrations from 0.1% to 1.0% increased both the intensity of SDS fragments and adverse cell outcomes. We also identified cellular remnants, by detecting phosphate and phosphocholine ions in PAA and CHAPS decellularized scaffolds. The present study demonstrates ToF-SIMS is not only a powerful tool for characterization of biologic scaffold surface molecular functionality, but also enables sensitive assessment of decellularization efficacy. We report here on the use of a highly sensitive analytical technique, time of flight secondary ion mass spectroscopy (ToF-SIMS) to characterize detergent decellularized scaffolds. ToF-SIMS detected cellular remnants and residual detergent fragments; increased intensity of the detergent fragments correlated with adverse cell matrix interactions. This study demonstrates the importance of maintaining a balance between cell removal and detergent disruption of matrix architecture and matrix surface ligand landscape. This study also demonstrates the power of ToF-SIMS for the characterization of decellularized scaffolds and capability for assessment of decellularization efficacy. Future use of biologic scaffolds in clinical tissue reconstruction will benefit from the fundamental results described in this work.

White LJ ，Taylor AJ ，Faulk DM ，Keane TJ ，Saldin LT ，Reing JE ，Swinehart IT ，Turner NJ ，Ratner BD ，Badylak SF ... -  《-》

The effect of detergents on the basement membrane complex of a biologic scaffold material.

The basement membrane complex (BMC) is a critical component of the extracellular matrix (ECM) that supports and facilitates the growth of cells. This study investigates four detergents commonly used in the process of tissue decellularization and their effect upon the BMC. The BMC of porcine urinary bladder was subjected to 3% Triton-X 100, 8mM 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (CHAPS), 4% sodium deoxycholate or 1% sodium dodecyl sulfate (SDS) for 24h. The BMC structure for each treatment group was assessed by immunolabeling, scanning electron microscopy (SEM) and second harmonic generation (SHG) imaging of the fiber network. The composition was assessed by quantification of dsDNA, glycosaminoglycans (GAG) and collagen content. The results showed that collagen fibers within samples treated with 1% SDS and 8mM CHAPS were denatured, and the ECM contained fewer GAG compared with samples treated with 3% Triton X-100 or 4% sodium deoxycholate. Human microvascular endothelial cells (HMEC) were seeded onto each BMC and cultured for 7 days. Cell-ECM interactions were investigated by immunolabeling for integrin β-1, SEM imaging and semi-quantitative assessment of cellular infiltration, phenotype and confluence. HMEC cultured on a BMC treated with 3% Triton X-100 were more confluent and had a normal phenotype compared with HMEC cultured on a BMC treated with 4% sodium deoxycholate, 8mM CHAPS and 1% SDS. Both 8mM CHAPS and 1% SDS damaged the BMC to the extent that seeded HMEC were able to infiltrate the damaged sub-basement membrane tissue, showed decreased confluence and an atypical phenotype. The choice of detergents used for tissue decellularization can have a marked effect upon the integrity of the BMC of the resultant bioscaffold.

Faulk DM ，Carruthers CA ，Warner HJ ，Kramer CR ，Reing JE ，Zhang L ，D'Amore A ，Badylak SF ... -  《-》

Fast, robust and effective decellularization of whole human livers using mild detergents and pressure controlled perfusion.

Human whole-liver perfusion-decellularization is an emerging technique for producing bio-scaffolds for tissue engineering purposes. The native liver extracellular matrix (ECM) provides a superior microenvironment for hepatic cells in terms of adhesion, survival and function. However, current decellularization protocols show a high degree of variation in duration. More robust and effective protocols are required, before human decellularized liver ECM can be considered for tissue engineering applications. The aim of this study is to apply pressure-controlled perfusion and test the efficacy of two different detergents in porcine and human livers. To test this, porcine livers were decellularized using two different protocols; a triton-x-100 (Tx100)-only protocol (N = 3) and a protocol in which Tx100 was combined with SDS (N = 3) while maintaining constant pressure of 120 mm Hg. Human livers (N = 3) with different characteristics (age, weight and fat content) discarded for transplantation were decellularized using an adapted version of the Tx-100-only protocol. Decellularization efficacy was determined by histology and analysis of DNA and RNA content. Furthermore, the preservation of ECM components was assessed. After completing the perfusion cycles with detergents the porcine livers from both protocols were completely white and transparent in color. After additional washing steps with water and DNase, the livers were completely decellularized, as no DNA or cell remnants could be detected. The Tx100-only protocol retained 1.5 times more collagen and 2.5 times more sGAG than the livers decellularized with Tx100 + SDS. The Tx100-only protocol was subsequently adapted for decellularizing whole-organ human livers. The human livers decellularized with pressure-controlled perfusion became off-white in color and semi-transparent within 20 h. Livers decellularized without pressure-controlled perfusion took 64-96 h to completely decellularize, but did not become white or transparent. The addition of pressure-controlled flow did remove all cells and double stranded DNA, but did not damage the ultra-structure of the ECM as was analyzed by histology and scanning electron microscopy. In addition, collagens and sGAG were maintained with the decellularized ECM. In conclusion, we established effective, robust and fast decellularization protocols for both porcine and human livers. With this protocol the duration of decellularization for whole-organ human livers has been shortened considerably. The increased pressure and flow did not damage the ECM, as major ECM components remained intact.

Willemse J ，Verstegen MMA ，Vermeulen A ，Schurink IJ ，Roest HP ，van der Laan LJW ，de Jonge J ... -  《-》

Detergent-Free Decellularization Preserves the Mechanical and Biological Integrity of Murine Tendon.

Marvin JC ，Mochida A ，Paredes J ，Vaughn B ，Andarawis-Puri N ... -  《-》