Email updates

Keep up to date with the latest news and content from JN and BioMed Central.

Open Access Research

Nanometric self-assembling peptide layers maintain adult hepatocyte phenotype in sandwich cultures

Jonathan Wu1, Núria Marí-Buyé23, Teresa Fernández Muiños2, Salvador Borrós3, Pietro Favia4 and Carlos E Semino125*

  • * Corresponding author: Carlos E Semino

  • † Equal contributors

Author Affiliations

1 Center for Biomedical Engineering, Massachusetts Institute of Technology, Boston, MA, USA

2 Department of Bioengineering, Tissue Engineering Laboratory, IQS-Universidad Ramon Llull, Barcelona, Spain

3 Grup d'Enginyeria de Materials, IQS-Universidad Ramon Llull, Barcelona, Spain

4 Department of Chemistry, University of Bari, Italy

5 Translational Centre for Regenerative Medicine (TRM-Leipzig), Universität Leipzig, Leipzig, Germany

For all author emails, please log on.

Journal of Nanobiotechnology 2010, 8:29  doi:10.1186/1477-3155-8-29

The electronic version of this article is the complete one and can be found online at:

Received:29 September 2010
Accepted:12 December 2010
Published:12 December 2010

© 2010 Wu et al; licensee BioMed Central Ltd.

This is an Open Access article distributed under the terms of the Creative Commons Attribution License (, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.



Isolated hepatocytes removed from their microenvironment soon lose their hepatospecific functions when cultured. Normally hepatocytes are commonly maintained under limited culture medium supply as well as scaffold thickness. Thus, the cells are forced into metabolic stress that degenerate liver specific functions. This study aims to improve hepatospecific activity by creating a platform based on classical collagen sandwich cultures.


The modified sandwich cultures replace collagen with self-assembling peptide, RAD16-I, combined with functional peptide motifs such as the integrin-binding sequence RGD and the laminin receptor binding sequence YIG to create a cell-instructive scaffold. In this work, we show that a plasma-deposited coating can be used to obtain a peptide layer thickness in the nanometric range, which in combination with the incorporation of functional peptide motifs have a positive effect on the expression of adult hepatocyte markers including albumin, CYP3A2 and HNF4-alpha.


This study demonstrates the capacity of sandwich cultures with modified instructive self-assembling peptides to promote cell-matrix interaction and the importance of thinner scaffold layers to overcome mass transfer problems. We believe that this bioengineered platform improves the existing hepatocyte culture methods to be used for predictive toxicology and eventually for hepatic assist technologies and future artificial organs.


The liver is an important and complex organ that plays a vital role in metabolism and is responsible for many important functions of the body including glycogen storage, plasma protein production, drug detoxification and xenobiotics metabolization. Due to the importance of this organ in many of the body's daily processes, liver malfunction often leads to death. Most of the activity of the liver can be attributed to hepatocytes, which make up 60-80% of the cytoplasmic mass of the liver [1,2]. Loss of hepatocyte function can result in acute or chronic liver disease and, as a result, substantially compromise the rest of the organ and the body. Many previous strategies have been implemented to maintain these hepatocyte functions in vitro, including the use of extracellular matrices such as the current standard, collagen [3-6], Matrigel [7] or liver derived basement membrane matrix [8]. However, the liver carries out and regulates numerous biochemical reactions that require the combined effort of specialized cells and tissues. As a result, isolated hepatocytes removed from their microenvironment soon lose their hepatospecific functions. Therefore, it is important for in vitro cultures to provide a system that closely simulates the local environment of an intact liver. Hepatocyte morphology is known to be closely linked to the functional output of the cells [9,10]. Standard cell cultures that seed cells on top of a monolayer of extracellular matrix have been used in the past to successfully culture hepatocytes; however, in certain instances hepatocellular functions become compromised because the cell no longer resembles a natural hepatocyte from a live liver. In many cases, specific cellular phenotypes are directly related to the cellular functions including cell survival, proliferation, differentiation, motility and gene expression [11,12]. Morphogenesis and assembly have been well established to be pertinent in the functional performance of liver-derived cells in vitro [10,13-15].

The double-gel "sandwich" method has been shown to improve morphology by embedding the cells between two layers to resemble in vivo conditions. Typically, one layer is set on the bottom of a culture dish and an additional layer is placed on top of the hepatocyte monolayer [4,16,17]. Under these conditions, hepatocytes have been shown to maintain some function and differentiation for up to several weeks. Verification of hepatocyte function was shown by specific mRNA [5,18] and protein secretion into culture media [16,19].

The highly oxygen-demanding hepatocytes are commonly maintained in Petri dishes under oxygen-deficient culture conditions and, thus, the cells are forced into anaerobic metabolic states [20]. Hence, oxygen supply in primary hepatocyte cultures is a crucial issue to be addressed. Generally, in cultures in Petri dishes oxygen consumption is no longer dependent upon hepatocellular uptake rates but it is limited by culture medium thickness as well as ambient oxygen concentrations. However, regardless of these constraints, hepatocytes are able to tolerate the hypoxic conditions by satisfying energy requirements through anaerobic glycolysis [20]. In any case, a previous study has shown that hepatospecific functions are oxygen-dependent, especially demonstrated in the poor production of albumin, urea and drug metabolites over a 14-day study period in common Petri dish models compared to enhanced oxygen delivery cultures on gas-permeable films [21]. Furthermore, it was shown as early as in 1968 that commonly used medium depths of 2-5 mm in Petri dishes rapidly produced hypoxic conditions when hepatocytes respired at their physiological rate [22]. Therefore, because plastic walls and culture medium are efficient barriers of oxygen diffusion, it is important to create a system in which a physiological oxygen supply is maintained [23,24].

More recently, the use of self-assembling peptides has been implemented and verified to be an excellent scaffold for cell culture [25-30]. Especially, RAD16-I (Table 1) has been extensively used in most of the studies. Not only does it provide an excellent three-dimensional microenvironment, but also it allows for the design and preparation of a tailor-made scaffold. This represents a novel approach to tissue engineering, which traditionally has relied on materials that were unknown in composition, like Matrigel, or not possible to design and alter, such as collagens. Furthermore, the versatility of the modification of this material allows for the introduction of functionalized peptide motifs, such as the signaling sequence GRGDSP (RGD) from collagen and YIGSR (YIG) from laminin [27,31], which target an integrin receptor and the 67 kDa laminin receptor, respectively [32]. Those motifs have been shown to be crucial in the activation of numerous vital cell functions including migration, proliferation, and cell attachment [33,34]. In one study, grafted adhesion peptides RGD and YIG were proved to promote hepatocyte adhesion to the surface by 60% [35]. Also, RGD-containing synthetic peptides coated on plastics promoted hepatocyte adhesion and differentiated function [36]. Recently, we combined RAD16-I with modified self-assembling peptides containing the integrin-binding sequence RGD, the laminin receptor binding sequence YIG and the heparin binding sequence present in collagen IV TAGSCLRKFSTM (TAG), in order to obtain a functionalized matrix scaffold [31]. We analyzed several liver-specific functions in terms of gene expression by means of quantitative PCR of albumin, hepatocytes nuclear factor 4-alpha (HNF4-alpha), multi-drug resistant protein 2 (MDR2) and tyrosine aminotransferase (TAT). When we compared two sandwich dimensions with layers of 1 mm and 0.5 mm, we observed, as expected, that the thinner configuration promoted upregulation of some specific genes due to the improvement of gas, nutrient and toxin exchange. However, when we analyzed expression of oxidative enzymes, in particular the cytochrome P450 3A2 (CYP3A2), the expression of the enzyme was downregulated at the same levels of the standard collagen sandwich cultures for all the conditions tested [31]. In a recent work, Wang et al. cultured freshly isolated rat hepatocytes over surfaces of self-assembling peptide gels, which improved many adult hepatic functions as compared to the double collagen layer or collagen sandwich culture [37]. In this type of surface, hepatocytes cultures developed into spheroids, easily to handle and with good hepatic performance. Nevertheless, this culture system does not allow an intimate interaction of the hepatocytes with the matrix. Moreover, a platform that uses a synthetic gel material in a sandwich configuration enables to rationally functionalize the matrix and thus to obtain specific cell responses.

Table 1. Self-assembling peptide sequences

Since the 70's in microelectronics, non equilibrium, cold, gas plasmas are effective methods utilized in material science and technology, including biomaterials, to tailor surface composition and materials properties. Plasma etching, plasma enhanced chemical vapor deposition (PECVD) and grafting of chemical functionalities by plasma are the three main surface modification processes. Appealing features of plasma techniques are the following: they work at room temperature; modifications are limited within the topmost hundreds nanometers of the materials, with no change of the bulk; use of very low quantities of gas/vapor reagents; no use of solvents; easy integration in industrial process lines [38]. Cold plasmas are used to tailor surface properties of materials intended to be used in biomedical applications. Due to their ability of tuning independently surface chemical composition and topography (e.g., roughness, patterns, etc.), plasma treatments allow processes like: the synthesis of non-fouling coatings, capable of discouraging the adhesion of proteins and cells at the biomaterial surface [39,40]; the optimization of the adhesion and behaviour of cells onto biomaterials [41-43] and membranes [44,45]; and the functionalization of surfaces for covalent immobilization of biomolecules like peptides [46] and saccharides [47,48] to mimic the extracellular matrix. One example are the plasma-deposited acrylic acid (PdAA) coatings [49], which are used in the biomedical field to provide the surface of biomaterials with -COOH groups for improving cell adhesion and growth [50-52] or for further immobilization of biomolecules [46-48]. Also, surfaces modified with pentafluorophenyl methacylate (PFM) have been successfully used to anchor biologically active motifs, since this monomer easily reacts with molecules containing primary amines, such as bioactive peptides [53,54].

Studies have tried cocultures of hepatocytes with other cells such as fibroblasts with the idea that nonparenchymal cell factors may promote and induce specific hepatocyte expression [55,56]. Others have tried to achieve in vivo level induction by focusing on culture substratum using complex matrices including fibronectin [57], extracts from liver [58] and Matrigel [59]. Currently, the best culture conditions for preserving primary hepatocytes are still unresolved. Therefore, in this work we develop a new platform where the hydrogel scaffold dimensions can be several orders of magnitude smaller (from 500 μm down to nanometric scale). Our strategy to control the peptide layer dimensions within a nanometric scale made possible to maintain the CYP3A2 activity for long periods in rat hepatocyte cultures. Briefly, in order to build our new biomaterial platform, we used two biocompatible porous membranes as main structural support for the hydrogel: PEEK-WC-PU, (poly(oxa-1,4-phenylene-oxo-1,4-phenylene-oxa-1,4-phenylene-3,3-(isobenzofurane-1,3-dihydro-1-oxo)-diyl-1,4-phenylene) modified with aliphatic polyurethane) [60] and PTFE (polytetrafluorethylene). These biocompatible membranes were chemically modified by means of two different plasma modifications in order to immobilize RAD16-I peptides. The anchored RAD16-I molecules directed the self-assembling of additional soluble RAD16-I peptides, which assemble forming a thin scaffold layer. Finally, we were able to obtain expression levels of albumin, CYP3A2 and HNF4-alpha similar to fresh hepatocytes by using the membranes with the controlled self-assembling peptide layer in a sandwich culture system during seven days.

Results and discussion

In this work, we attempt to address the concerns of traditional hepatocyte culture methods by combining tissue engineering technologies. Our sandwich culture method is adjusted from the traditional double gel layer "sandwich" technique to address diffusion issues. Instead of culturing the hepatocytes under a thick second layer of peptide, the cells are entrapped under a biocompatible porous membrane (PEEK-WC-PU or PTFE), previously modified through plasma processes to allow dimensional control of a thin hydrogel-coating layer. This self-assembling peptide layer contains signaling peptide sequences to promote specific cell responses, mimicking the cell-matrix interactions that are lost in isolated hepatocytes.

Dimensional control of self-assembling peptide layer

In this work, membrane surfaces were modified by two non-equilibrium plasma processes: plasma enhanced chemical vapor deposition (PECVD) and plasma grafting (PG). Plasma treatments can be used to tune surface properties, including electric charge, wettability, free energy, surface chemistry and morphology. This ability to optimize surface conditions can affect cellular behavior and attachment either directly, for instance, through guided cell spreading or indirectly, for example, through controlled protein adsorption on the surface. The more recent and advanced uses in plasma treatments involve the immobilization of biomolecules onto biomaterial surfaces to promote specific cellular responses at the molecular and cellular levels [47,54,60]. In this study, membranes were modified by plasma deposition of acrylic acid (hereby abbreviated as "PdAA") or by plasma grafting of pentafluorophenyl methacrylate, PFM (hereby abbreviated as "PgPFM"). In the first case, the monomer was subjected to plasma and then polymerized on the surface whereas in the second case, the surface was activated by plasma creating active groups that react with the oncoming monomer. Both modifications would allow the posterior attachment of a peptide to the surface. Therefore, we developed a method based on two simple steps: 1, RAD16-I self-assembling peptides containing a free amino termini group (NH2-RAD16-I) were immobilized on the surface of a porous membranes (Figure 1A and 1B) and 2, then RAD16-I peptide solution (1% (w/v)) was incubated over the peptide-immobilized membranes, followed by a water rinse to remove unbound and unassembled peptides (Figure 1C). The attached peptide, with the same aminoacid sequence as RAD16-I, acted as an anchor to stabilize the self-assembled nanofibers formed from the RAD16-I peptide solution. Peptide attachment to the membranes (PEEK or PTFE) was confirmed by x-ray photoelectron spectroscopy (XPS) and by detection of fluorescein-conjugated peptides (data not shown).

thumbnailFigure 1. Development of nanometric self-assembling peptide layers on thin porous membranes. (A) Plasma deposition of acrylic acid onto membrane surfaces. RAD16-I peptide sequences are immobilized to the deposited -COOH. (B) Plasma deposition of pentafluorophenyl methacrylate (PFM) onto membrane surfaces. RAD16-I peptide sequences are immobilized to the deposited PFM. (C) Model describing the formation of a thin layer of self-assembling peptide gel on a membrane substrate using immobilized self-assembling peptides as attachment points.

SEM was used to evaluate the formation of the hydrogel layer on the membranes. As expected at this magnification, alterations due to plasma treatment or RAD16-I peptide immobilization were not visibly apparent (Figure 2 and 3). In the case of PEEK-WC-PU membranes modified with the RAD16-I peptide (PEEK-WC-PU/PdAA/RAD16-I), the native membranes (PEEK-WC-PU) and the acrylic acid modified membranes (PEEK-WC-PU/PdAA) were used as controls. After one-hour incubation with the self-assembling peptide solution at 1% (w/v), followed by water rinsing, the native PEEK-WC-PU membrane showed no fiber formation and the PEEK-WC-PU/PdAA membrane displayed some non-homogeneous peptide fiber attachment (Figure 2). Interestingly, the PEEK-WC-PU/PdAA/RAD16-I membrane demonstrated the best fiber formation of the three conditions (Figure 2). The peptide layer was both thin and homogenous, creating a nanometric mesh, which seemed not to obstruct the pores of the native membrane beneath. On the other hand, self-assembling nanofiber formation was also observed on the Biopore PTFE membranes (Figure 3A). In this case, only the native PTFE membrane was used to compare against the peptide-modified PTFE (PTFE/PgPFM/RAD16-I). Surprisingly, after the one-hour incubation and rinsing, both the native and modified PTFE membranes presented the same fiber formation pattern of self-assembling peptide. The peptides seemed to have assembled into a very thin web layer using the protruding features of the membrane. Closer examination revealed a mesh of individual fibers in the membrane pores (Figure 3B).

thumbnailFigure 2. Self-assembling nanofiber network development on PEEK-WU-PC membranes. SEM images of fiber formation of RAD16-I self-assembling peptide on unmodified PEEK-WC-PU membranes (top row), plasma-deposited acrylic acid PEEK-WC-PU membranes, PEEK-WC-PU/PdAA (middle row), and plasma-modified RAD16-immobilized PEEK-WC-PU membranes, PEEK-WC-PU/PdAA/RAD16-I (bottom row), after incubation in absence (left column) or presence (right column) of soluble RAD16-I peptide.

thumbnailFigure 3. Self-assembling nanofiber network development on PTFE porous membranes. (A) SEM images of fiber formation of RAD16-I self-assembling peptide on unmodified PTFE membranes (top row) and plasma modified RAD16-I immobilized PTFE membranes, PTFE/PdPFM/RAD16-I membranes (bottom row) after incubation in absence (left column) or presence (right column) of soluble RAD16-I peptide. (B) Close up of a SEM image of a PTFE/PdPFM/RAD16-I membrane after incubation in presence of of soluble RAD16-I peptide.

Hepatocyte attachment on thin hydrogel layer

The next objective was to assess the attachment of hepatocytes onto the self-assembling peptide-coated modified membranes. To determine whether cellular attachment was specifically enhanced by the presence of the self-assembling peptide layer, the hepatocytes were incubated for 8 hours and then the media was changed in order to remove dead cells (Figure 4A). After 24 hours post cell-seeding the PEEK-WC-PU/PdAA did not bind any cells, as expected (Figure 5). Likewise, there was no cellular attachment apparent on the PEEK-WC-PU/PdAA that was previously incubated with soluble peptide, which yielded a patchy, variable, and unreliable fiber formation (Figure 2). On the other hand, the PEEK-WC-PU/PdAA/RAD16-I membranes demonstrated cell binding in both conditions (Figure 5). Without the peptide incubation, a few cells unexpectedly still attached to the surface. There was no fiber matrix present, however, the immobilized RAD16-I peptides might have provided a more favorable cell-attaching surface than the PEEK-WC-PU/PdAA substrate. Finally, with the peptide incubation, the surface was completely filled with hepatocytes. It is apparent that the self-assembling peptide fiber network vastly enhanced hepatocyte attachment. A close-up image of one of the hepatocytes reveals an intricate cellular attachment with the substrate (Figure 6).

thumbnailFigure 4. Self-assembling peptide-coated membranes seeded with hepatocytes. (A) Hepatocytes are loaded on top of a thin layer of self-assembling peptide gel on a membrane substrate described in Figure 1. (B) A tissue culture insert is coated with a layer of ~0.5 mm of self-assembling peptides. (C) Gel formation is induced by addition of media, and the inverted cell-seeded membrane from A is placed on top of the equilibrated gel. (D) Finally, the sandwich is covered with media. Therefore, the new sandwich culture system consist of a hydrogel layer at the bottom (~0.5 mm) covered by a thin layer of self-assembling peptide-coated on a porous membrane (PEEK or PTFE). The hepatocytes are placed in within both layers.

thumbnailFigure 5. Hepatocyte attachment on a self-assembling peptide covered PEEK-WC-PU porous membrane. SEM images of hepatocyte attachment with (left column) and without (right column) RAD16-I incubation on plasma-deposited acrylic acid (top row, PEEK-WC-PU/PdAA) and plasma-modified RAD16-immobilized (bottom row, PEEK-WC-PU/PdAA/RAD16-I) PEEK-WC-PU membranes.

thumbnailFigure 6. Close-up images of a hepatocyte attached on a self-assembling peptide covered PEEK-WU-PC porous membrane. SEM images of a single hepatocyte on PEEK-WC-PU/PdAA/RAD16-I+RAD16-I. At closer magnifications, cytoplasmic projections seem to adhere to the self-assembling peptide substrate (from left to right).

On the other hand, the native (PTFE) and peptide-modified (PTFE/pgPFM/RAD16-I) membranes, both incubated with soluble RAD16-I, supported hepatocyte attachment (Figure 7). Interestingly, the morphology of the cells for each of the membranes was very different. For instance, on the native membrane, the hepatocytes remained round and spherical throughout the entire surface. Likewise, the cells tended to clump and form spheroids. On the other hand, the peptide-modified membrane mainly contained cells with a flat and extended morphology (Figure 7). The cells on this membrane tended not to cluster and form spheroids. The spread and extended morphology is more favorable for hepatocytes to develop cell-matrix and cell-cell interactions. For example, this morphology could promote polarization and the formation of bile canilicular spaces between neighboring cells. Although both membranes were visibly identical, we propose that the immobilized RAD16-I created an anchor for the peptide layer on the peptide-modified PTFE and thus generated a stronger interaction between the nanofiber coating and the membrane. We speculate that cell-matrix interaction was more stable in the peptide-modified membranes than in the native one promoting the development of a flat and extended morphology. When nanofibers were not immobilized, the cells appear to pull off surrounding unanchored peptide without being able to interact with the membrane, and instead interacting with surrounding cells to form clusters.

thumbnailFigure 7. Hepatocyte attachment on a self-assembling peptide covered PTFE porous membrane. SEM images of hepatocyte attachment with RAD16-I incubation on native PTFE (left column, PTFE + RAD16-I) and plasma-grafted PFM RAD16-immobilized PTFE membranes (right column, PTFE/PgPFM/RAD16-I + RAD16-I). Note: SEM image of hepatocyte attachment on native PTFE membrane. Hepatocytes appear to pull off surrounding peptide without the anchorage of immobilized peptides and form clusters. The cells are unable to interact with the rigid substrate beneath the peptide and, thus, do not achieve a flat morphology (see bottom left panel). Instead, hepatocyte attachment on PFM RAD16-I-immobilized PTFE membranes ends in the formation of cytoplasmic projections visibly adhere to the self-assembling fibers.

Modified Sandwich Culture of Primary Hepatocytes

After demonstrating that our substrates were able to promote cell attachment and proper morphology, the following objective was to determine to what extent the self-assembling peptides enhanced hepatocellular function, especially CYP3A2 expression. In a recent publication, we observed that using self-assembling peptide sandwich with layer dimensions between 0.5-1.0 mm, the expression of oxidative enzymes, in particular CYP3A2, in all the conditions tested was highly downregulated [31].

Thus, modified peptide sandwich cultures were prepared similar to typical sandwich cultures except for the top layer of soluble peptide that was substituted with the inverted cell-seeded modified membrane (Figure 4). Cultures were observed over a week-long period and quantitative PCR (qPCR) was performed to measure hepatospecific biomarkers expressed in fresh hepatocytes. Gene expression profile of albumin, CYP3A2, and HNF4-alpha relative to gene expression in freshly isolated hepatocytes over a period of seven days was initially performed using modified sandwich cultures with PEEK-WC-PU membranes (Figure 8). Results were attained in three separate experiments presented on a log base 2 scale. Therefore, a 2-fold upregulation is equivalent to 4 fold (= 22) increased expression. In addition, values between -1 and +1 are considered equivalent to fresh hepatocyte levels.

thumbnailFigure 8. Expression of hepatocyte markers of cells in sandwich cultures of self-assembling peptide scaffolds and PEEK-WC-PU membranes. (A) Gene expression profile of albumin, CYP3A2, and HNF4-alpha obtained by quantitative PCR relative to gene expression in freshly isolated hepatocytes. Cells cultured on modified PEEK-WC-PU membranes incubated with RAD16-I. (B) Comparison of CYP3A2 gene expression relative to freshly isolated hepatocytes by quantitative PCR with previous results at 7 days of collagen cultures (collagen sandwich) are compared with both self-assembling peptide RAD16-I sandwich cultures (RAD16-I sandwich) and sandwich cultures of self-assembling peptides RAD16-I and PEEK-WC-PU membranes (RAD16-I (PEEK)). Data in A and B is presented as mean ± SD (with statistical significances indicated as ** for p < 0.01 and *** for p < 0.001).

After 24 hours post-seeding, the cells expressed great levels of albumin and HNF4-alpha (Figure 8A). Albumin expression was close to fresh levels at day 1, then began to slightly decline until day 4 and by day 7, appeared to have improved to -3-fold downregulation. On the other hand, HNF4-alpha expression maintained within a close range to fresh cell levels. CYP3A2 was downregulated at day 1 and slightly evened off around a -7-fold after a week. However, our system at this point is still about 1.5-fold better than the current gold standard method of culturing hepatocytes with collagen or double gel layers of RAD16-I self-assembling peptides (Figure 8B).

Then, in order to see if PTFE membranes were able to increase the expression profile of CYP3A2 due to its bigger pore size and as consequence, possible improvement of mass transfer issues, gene expression relative to freshly isolated hepatocytes over a period of seven days -for modified sandwich cultures using peptide-modified PTFE membranes- was also monitored. In addition we decided to study the effect that functionalized nanofiber network -with biological active motifs- could have on specific cell-receptor signals and therefore improving hepatocyte phenotype. Thus, the nanofiber layer was prepared by using 100% of RAD16-I peptide or blended with small percentages of functionalized ones (RGD and YIG peptides) carrying receptor-binding sequences (Table 1). Different layer compositions were tested: RAD16-I, 5% RGD in RAD16-I, 5% YIG in RAD16-I, and a mix of 2.5% RGD and 2.5% YIG in RAD16-I. RNA samples were collected at day 7 to determine if the peptide layer and the functional motifs enhanced CYP3A2 expression.

Interestingly, CYP3A2 expression in RAD16-I-modified PTFE membranes increased dramatically over 7 days in culture compared to the previous RAD16-I-PEEK-WC-PU membranes (Figure 9). Although, RGD PTFE membranes (5% RGD/95% RAD16-I) were similar to RAD16-I a good improvement in CYP3A2 expression was observed with YIG PTFE ones (5% YIG/95% RAD16-I) and even better with the MIX PTFE membranes (2.5% RGD/2.5% YIG/95% RAD16-I), which provided a vast improvement over the RAD16 PTFE condition (Figure 9). Again, compared to the data from the PEEK-WC-PU membranes, the day 7 CYP3A2 levels of all conditions on the PTFE membranes are significantly better (Figure 9). With respect to the previous PEEK-WC-PU material, the RAD16-I condition on PTFE provided a 3-fold improvement. This was about an x8 (= 23) increase in gene expression. We conjecture this enhancement to be due to physical differences between membrane geometry and topography. As seen in the SEM images (see Figure 2 and 3), the porosity of the PTFE membrane was much higher and the pore sizes were much larger compared to PEEK ones. Tying back to our hypothesis of culture improvement by reducing oxygen and nutrient diffusion barriers, the PTFE membranes provide much less of an obstruction and facilitate better exchange with the microenvironment. In comparison to the other PTFE conditions, the RAD16-I and RGD cultures appear to be on par with each other. The YIG condition slightly improves upon the previous two. Likewise, the mix condition of RGD and YIG furthermore enhances the CYP3A2 gene expression (at mRNA levels) to almost -2.5-fold. This clearly indicates the positive effect on CYP3A2 increase caused by the presence of the bioactive motifs YIG alone or the mix YIG+RGD. This is a tremendous improvement over the standard collagen method that produced about a -10.5-fold downregulation. This 8-fold difference translates to a 256-fold (= 28) improvement on gene expression at the level of mRNA in the MIX modified sandwich system as compared to the typical collagen sandwich culture (Figure 9).

thumbnailFigure 9. Expression of CYP3A2 of in sandwich cultures of self-assembling peptide scaffolds and PTFE membranes. Comparison of CYP3A2 gene expression relative to freshly isolated hepatocytes at day 7 by quantitative PCR with previous results from Collagen sandwiches and RAD16-I sandwiches [31], and the performed in this manuscript with PEEK-WC-PU membranes and PTFE membranes. Particularly, cultures YIG (PTFE) and MIX (PTFE) are significantly different from RAD16-I (PTFE) with p < 0.05 and p < 0.001, respectively. Data is presented as mean ± SD (with statistical significances indicated as * for p < 0.05 and *** for p < 0.001).


We have successfully shown that our novel bioengineering platform can maintain expression levels of albumin, CYP3A2 and HNF4-alpha similar to fresh hepatocytes for as long as a week. This was ultimately done by improving the biophysical features of traditional sandwich cultures by optimizing the top peptide layer dimension to orders of nanometers to facilitate oxygen exchange and nutrient diffusion. Additionally, the biochemical aspects of typical cultures were enhanced by engineering the scaffold with the introduction of functional peptide motifs to strategically target certain cell receptors responsible for the activation of numerous vital cell functions. We believe that our new platform has improved significantly the existing culture methods, opening a new possibility for the pharmacological industry.


Hepatocyte Isolation

Hepatocytes were isolated from male Fisher rats weighing 150-180 g using a modification of the Seglen 2-step collagenase perfusion procedure [61]. Cell yield and viability were determined via trypan blue exclusion and hemocytometry. Typically, 250-300 million hepatocytes were harvested per rat liver with viability ranging from 85-92%. Following isolation, cells were initially suspended in Hepatocyte Culture Medium (HCM, Cambrex, MD, CC-3198), containing 2% fatty acid free BSA (bovine serum albumin), transferrin, insulin, recombinant human EGF (epithelial growth factor), ascorbic acid, hydrocortisone and gentamycin/amphotericin.

Plasma Modification of Membranes

PEEK-WC-PU membranes were kindly provided by the De Bartolo Lab (Institute on Membrane Technology, National Research Council of Italy). PTFE membranes were purchased (Biopore, BCGM00010).

PEEK-WC-PU membranes were modified with a PE-CVD surface functionalization process fed with acrylic acid (AA) vapors in order to create a thin stable plasma-deposited acrylic acid (pdAA) coating characterized by a certain density of -COOH groups. Membranes were plasma-coated in a radio frequency (13.56 MHz) driven stainless-steel parallel plate plasma reactor [51]. AA vapors were fed from a liquid reservoir kept a room temperature, at a pressure of 0.2 mbar, and samples were exposed at 100 W for 5 min (PEEK-WC-PU/PdAA). Before use AA was degassed with freeze-thaw cycles. The deposition results in 10 ± 1 nm thick coatings characterized by a surface density of about 4% carboxylic groups over all carbon atoms of the coatings, and a O/C atomic ratio of 0.29, as measured by X-rays photoelectron Spectroscopy [51]. PdAA-coated membranes substrates were then immersed in 1-ethyl-3-(3-dimethylamino-propyl) carbodiimide (EDC) and N-hydroxysuccinimide (NHS) in morpholine ethane sulfonate (MES) buffer to activate -COOH groups. Afterwards, membranes were incubated overnight in a water solution of NH2-GG-RAD16-I (10 mg/ml) at 37°C to obtain the final PEEK-WC-PU membranes with immobilized RAD16-I (PEEK-WC-PU/PdAA/RAD16-I) (see Figure 1A).

Instead, PTFE membranes were modified by graft polymerization of pentafluorophenyl methacrylate (PFM) in a two-step process. The membranes were placed in a cylindrical Pyrex reactor equipped with a copper coil that generates plasma under vacuum conditions (0.02 mbar). Argon was fed into the chamber increasing the pressure to approximately 0.06 mbar and samples were exposed to argon plasma at 50 W for 5 min. Afterwards, argon inflow was closed and PFM vapor was introduced into the reactor and allowed to polymerize for 1 min (PTFE/PgPFM) without plasma. After treatment, membranes were soaked overnight in an aqueous solution of NH2-GG-RAD16-I (10 mg/ml) at 37°C to obtain the final PTFE membranes with immobilized RAD16-I (PTFE/PgPFM/RAD16-I) (see Figure 1B).

RAD16-I peptide layer membrane coating

All membranes, including the native PEEK-WC-PU, PEEK-WC-PU/PdAA, PEEK-WC-PU/PdAA/RAD16-I, native PTFE, PTFE/PgPFM and PTFE/PgPFM/RAD16-I membranes were sterilized using a 70% ethanol. After the ethanol rinse, the membranes were autoclaved for 20 min at 120°C, followed by a 10 min drying step.

PuraMatrix RAD16-I peptide (BD Biosciences, 354250) was used to coat the surface of the membranes. In cases where modified peptides (RGD or YIG) were included, the modified peptides were blended in a 95:5 proportion with the prototypic peptide RAD16-I (prototypic:modified). A volume of 50 μl of peptide was used to thinly cover the surface of the 0.5 in × 0.5 in square membrane samples. The self-assembling peptide solution becomes a hydrogel through contact with salt-containing buffers or media [62]. However, in order to control the thickness of the peptide layer, gelation was not initialized through the introduction of media, but the soluble peptide was allowed to incubate for an hour to permit any self-assembling to occur with the immobilized peptide strands (Figure 1C). Following the incubation, a rinse step was included that entailed dipping the coated membranes into deionized water ten times in succession to remove any non-assembled peptide.

Peptide sandwich preparation

In order to seed the cells on the peptide-coated membranes, these were incubated with a volume of hepatocyte cell suspension in HCM at a final density of 65,000 cells/cm2 and left to attach in a 37°C incubator for 8 h (Figure 4A). Following the 8 h attachment period (optimized attachment time), the medium was changed to remove dead cells. Meanwhile, the bottom peptide layer was prepared by loading 0.25 ml of peptide into a Millicell tissue culture insert (Millipore, PICM 03050). Then, 1.5 ml of HCM were added underneath the insert membrane to induce gelation, forming a 1 mm-thick gel (Figure 4B). Following the gelation of the peptide, 0.4 ml of HCM were added into the insert and the gel was allowed to equilibrate for 30 min in an incubator at 37°C. To complete the peptide sandwich, the membrane containing the attached cells was inverted on top of the gel layer in the tissue culture insert (Figure 4C). Then, 0.3 ml of HCM was added to the inside of the insert (Figure 4D). Cultures were maintained in a water-jacketed incubator at 37°C and 5% CO2. Media was changed every day so that a fresh reservoir of 1.6 ml surrounded the outside of the insert and 0.3 ml replaced the inside of the insert.

SEM sample preparation

Membrane samples for all conditions (treated/not treated with soluble peptide, incubated/not incubated with hepatocytes) were submerged for 20 min in a fixative mixture containing 2% glutaraldehyde (Sigma, G7526) + 3% paraformaldehyde (Sigma, P6148) in PBS (Invitrogen, 14040). Following the fixing, a series of ethanol dehydration steps were performed, which included incubating the samples for 15 min in 50% ethanol, then 30 min in 75% ethanol, then 60 min in 90% ethanol, followed by two changes of 100% ethanol, where the samples were kept until the next step. Using a Tousimis Super Critical Point Autosamdri815 Dryer, the ethanol-saturated samples underwent a process in which the ethanol was slowly exchanged with CO2 and then dried at the critical pressure and temperature of CO2. The dried samples were subsequently sputter-coated in vacuum (Denton Vacuum, LLC) with gold (30 sec, approximate thickness 4-5 nm). SEM was carried out using a JEOL JSM 6060 Scanning Electron Microscope at an accelerating voltage of 5 kV.

Quantitative reverse transcriptase PCR (qRTPCR)

RNA samples were obtained by treating cells with Trizol Reagent (Invitrogen, 15596-026) and storing samples in a -80°C freezer until use. Samples were homogenized through pipetting with a 20G needle. Chloroform (Mallinckrodt Chemicals, 4440-04) was mixed thoroughly with each sample and then spun to separate the protein and RNA. The protein fractions were individually stored in a -20°C freezer for further assays. The "clear" RNA supernatants of the samples were transferred to separate tubes with equal volumes of 70% ethanol. Using the RNEasy Mini Kit (Qiagen, 74104), the RNA mixture was extracted using a series of reagents and spin cycles. RNA of freshly isolated hepatocytes was extracted and used as a control. The obtained RNA samples were quantified and the quality assessed using a NanoDrop ND-1000 Spectrophotometer. RNA samples of poor quality (260/280 and 260/230 ratios not approximately 2.0) were cleaned up using the Qiagen RNA Clean Up procedure included in the RNEasy Mini Kit. The RNA samples were treated with DNAse Buffer and DNAse I (Invitrogen, 18068) to remove contaminant genomic DNA. An amount of 150 ng of RNA for each sample was reversed transcribed with an Omniscript Reverse Transcription Kit (Qiagen, 205111). EDTA was added to each sample and then incubated at 65°C for 10 min. Next, a master mix of DEPC water, dNTP, Random Hexamers, RNase Inhibitor, RT Buffer and Omniscript RTO Reverse Transcriptase was added to each sample and incubated at 37°C for 1.5 h. Quantitative PCR was performed using QuantiTect SYBR Green PCR kit (Qiagen, 204143) in a MJ Opticon Monitor instrument (Applied Biosystems). PCR primers were designed to obtain 150-200 base pair amplification product. The primer sequences used are shown in Table 2. The PCR protocol entailed: incubation at 95°C for 15 min, followed by 45 cycles of incubating the samples at 94°C for 15s, annealing at 51-55°C for 30s and extending at 72°C for 30s. A melting curve was performed to assess the purity of the products formed. Using the 2-ΔΔCt method, relative gene fold changes were determined compared to the ribosomal unit 18s as a housekeeping gene. Samples were then compared to the gene expression in freshly isolated hepatocytes. P-values of a test of significance were calculated using Excel.

Table 2. RT-PCR primers of albumin, HNF4-α, CYP3A2, and the housekeeping gene, 18S

Competing interests

The authors declare that they have no competing interests.

Authors' contributions

JB and NMB developed the nanometric self-assembling peptide layers on membranes, and contributed to electron microscopy techniques and data analysis. JB carried out hepatocyte culture experiments and gene expression technique. NMB designed and prepared the PFM-functionalized membranes and RAD16-I peptide anchorage. TFM contributed to gene expression experiments and data analysis. SB participated in the design of the PFM-functionalized membranes. PF developed AA-modified membranes as well as RAD16-I peptide immobilization. CES conceived of the study, and contributed in its design and coordination. JB, NMB and CES wrote the paper. All authors read and approved the final manuscript.


We greatly thank Laura Vineyard for isolating and providing the hepatocytes, Loredana de Bartolo for providing the PEEK-WC-PU membranes and Andreas Heilmann for some SEM pictures. NMB acknowledges financial support from DURSI (Generalitat de Catalunya) and the European Social Fund. This work was supported by the grants: NIH I-RO1-EB003805-01A1 to CES and LIVEBIOMAT (6th Frame Program) Project number 013653 to CES and PF.


  1. Michalopoulos GK, DeFrances MC: Liver regeneration.

    Science 1997, 276:60-66. PubMed Abstract | Publisher Full Text OpenURL

  2. Kmieć Z: Cooperation of liver cells in health and disease.

    Adv Anat Embryol Cell Biol 2001, 161:III-XIII.


    PubMed Abstract OpenURL

  3. Ben-Ze'ev A, Robinson GS, Bucher NL, Farmer SR: Cell-cell and cell-matrix interactions differentially regulate the expression of hepatic and cytoskeletal genes in primary cultures of rat hepatocytes.

    Proc Natl Acad Sci USA 1988, 85:2161-2165. PubMed Abstract | PubMed Central Full Text OpenURL

  4. Dunn JC, Yarmush ML, Koebe HG, Tompkins RG: Hepatocyte function and extracellular matrix geometry: long-term culture in a sandwich configuration.

    FASEB J 1989, 3:174-177. PubMed Abstract | Publisher Full Text OpenURL

  5. Dunn JC, Tompkins RG, Yarmush ML: Long-term in vitro function of adult hepatocytes in a collagen sandwich configuration.

    Biotechnol Prog 1991, 7:237-245. PubMed Abstract | Publisher Full Text OpenURL

  6. Berthiaume F, Moghe PV, Toner M, Yarmush ML: Effect of extracellular matrix topology on cell structure, function, and physiological responsiveness: hepatocytes cultured in a sandwich configuration.

    FASEB J 1996, 10:1471-1484. PubMed Abstract | Publisher Full Text OpenURL

  7. Silva JM, Morin PE, Day SH, Kennedy BP, Payette P, Rushmore T, Yergey JA, Nicoll-Griffith DA: Refinement of an in vitro cell model for cytochrome P450 induction.

    Drug Metab Dispos 1998, 26:490-496. PubMed Abstract | Publisher Full Text OpenURL

  8. Zeisberg M, Kramer K, Sindhi N, Sarkar P, Upton M, Kalluri R: De-differentiation of primary human hepatocytes depends on the composition of specialized liver basement membrane.

    Mol Cell Biochem 2006, 283:181-189. PubMed Abstract | Publisher Full Text OpenURL

  9. Semler EJ, Moghe PV: Engineering hepatocyte functional fate through growth factor dynamics: the role of cell morphologic priming.

    Biotechnol Bioeng 2001, 75:510-520. PubMed Abstract | Publisher Full Text OpenURL

  10. Singhvi R, Kumar A, Lopez GP, Stephanopoulos GN, Wang DI, Whitesides GM, Ingber DE: Engineering cell shape and function.

    Science 1994, 264:696-698. PubMed Abstract | Publisher Full Text OpenURL

  11. Huang S, Chen CS, Ingber DE: Control of cyclin D1, p27(Kip1), and cell cycle progression in human capillary endothelial cells by cell shape and cytoskeletal tension.

    Mol Biol Cell 1998, 9:3179-3193. PubMed Abstract | PubMed Central Full Text OpenURL

  12. Singhvi R, Stephanopoulos G, Wang DI: Effects of substratum morphology on cell physiology.

    Biotechnol Bioeng 1994, 43:764-771. PubMed Abstract | Publisher Full Text OpenURL

  13. Hansen LK, Hsiao C, Friend JR, Wu FJ, Bridge GA, Remmel RP, Cerra FB, Hu W: Enhanced morphology and function in hepatocyte spheroids: a model of tissue self-asembly.

    Tissue Eng 1998, 4:65-74. Publisher Full Text OpenURL

  14. Torok E, Pollok JM, Ma PX, Kaufmann PM, Dandri M, Petersen J, Burda MR, Kluth D, Perner F, Rogiers X: Optimization of hepatocyte spheroid formation for hepatic tissue engineering on three-dimensional biodegradable polymer within a flow bioreactor prior to implantation.

    Cells Tissues Organs 2001, 169:34-41. PubMed Abstract | Publisher Full Text OpenURL

  15. Yuasa C, Tomita Y, Shono M, Ishimura K, Ichihara A: Importance of cell aggregation for expression of liver functions and regeneration demonstrated with primary cultured hepatocytes.

    J Cell Physiol 1993, 156:522-530. PubMed Abstract | Publisher Full Text OpenURL

  16. Ryan CM, Carter EA, Jenkins RL, Sterling LM, Yarmush ML, Malt RA, Tompkins RG: Isolation and long-term culture of human hepatocytes.

    Surgery 1993, 113:48-54. PubMed Abstract OpenURL

  17. Knop E, Bader A, Boker K, Pichlmayr R, Sewing KF: Ultrastructural and functional differentiation of hepatocytes under long-term culture conditions.

    Anat Rec 1995, 242:337-349. PubMed Abstract | Publisher Full Text OpenURL

  18. Chen HL, Wu HL, Fon CC, Chen PJ, Lai MY, Chen DS: Long-term culture of hepatocytes from human adults.

    J Biomed Sci 1998, 5:435-440. PubMed Abstract | Publisher Full Text OpenURL

  19. Pahernik SA, Thasler WE, Mueller-Hoecker J, Schildberg FW, Koebe HG: Hypothernic storage of pig hepatocytes: influence of different storage solutions and cell density.

    Cryobiology 1996, 33:552-566. PubMed Abstract | Publisher Full Text OpenURL

  20. Jensen MD, Wallach DF, Sherwood P: Diffusion in tissue cultures on gas-permeable and impermeable supports.

    J Theor Biol 1976, 56:443-458. PubMed Abstract | Publisher Full Text OpenURL

  21. Bader A, Fruhauf N, Tiedge M, Drinkgern M, De BL, Borlak JT, Steinhoff G, Haverich A: Enhanced oxygen delivery reverses anaerobic metabolic states in prolonged sandwich rat hepatocyte culture.

    Exp Cell Res 1999, 246:221-232. PubMed Abstract | Publisher Full Text OpenURL

  22. McLimans WF, Crouse EJ, Tunnah KV, Moore GE: Kinetics of gas diffusion in mammalian cell culture systems. I. Experimental.

    Biotechnology and bioengineering 1968, 10:725. Publisher Full Text OpenURL

  23. Bader A, Knop E, Kern A, Boker K, Fruhauf N, Crome O, Esselmann H, Pape C, Kempka G, Sewing KF: 3-D coculture of hepatic sinusoidal cells with primary hepatocytes-design of an organotypical model.

    Exp Cell Res 1996, 226:223-233. PubMed Abstract | Publisher Full Text OpenURL

  24. Catapano G, De BL, Lombardi CP, Drioli E: The effect of oxygen transport resistances on the viability and functions of isolated rat hepatocytes.

    Int J Artif Organs 1996, 19:61-71. PubMed Abstract OpenURL

  25. Quintana L, Muinos TF, Genove E, Del Mar OM, Borros S, Semino CE: Early tissue patterning recreated by mouse embryonic fibroblasts in a three-dimensional environment.

    Tissue Eng Part A 2009, 15:45-54. PubMed Abstract | Publisher Full Text | PubMed Central Full Text OpenURL

  26. Garreta E, Genove E, Borros S, Semino CE: Osteogenic differentiation of mouse embryonic stem cells and mouse embryonic fibroblasts in a three-dimensional self-assembling peptide scaffold.

    Tissue Eng 2006, 12:2215-2227. PubMed Abstract | Publisher Full Text OpenURL

  27. Genove E, Shen C, Zhang S, Semino CE: The effect of functionalized self-assembling peptide scaffolds on human aortic endothelial cell function.

    Biomaterials 2005, 26:3341-3351. PubMed Abstract | Publisher Full Text OpenURL

  28. Semino CE, Kasahara J, Hayashi Y, Zhang S: Entrapment of migrating hippocampal neural cells in three-dimensional peptide nanofiber scaffold.

    Tissue Eng 2004, 10:643-655. PubMed Abstract | Publisher Full Text OpenURL

  29. Semino CE: Can We Build Artificial Stem Cell Compartments?

    J Biomed Biotechnol 2003, 2003:164-169. PubMed Abstract | Publisher Full Text | PubMed Central Full Text OpenURL

  30. Kisiday J, Jin M, Kurz B, Hung H, Semino C, Zhang S, Grodzinsky AJ: Self-assembling peptide hydrogel fosters chondrocyte extracellular matrix production and cell division: implications for cartilage tissue repair.

    Proc Natl Acad Sci USA 2002, 99:9996-10001. PubMed Abstract | Publisher Full Text | PubMed Central Full Text OpenURL

  31. Genove E, Schmitmeier S, Sala A, Borros S, Bader A, Griffith LG, Semino CE: Functionalized self-assembling peptide hydrogel enhance maintenance of hepatocyte activity in vitro.

    J Cell Mol Med 2009, 13:3387-3397. PubMed Abstract | Publisher Full Text OpenURL

  32. Graf J, Ogle RC, Robey FA, Sasaki M, Martin GR, Yamada Y, Kleinman HK: A pentapeptide from the laminin B1 chain mediates cell adhesion and binds the 67,000 laminin receptor.

    Biochemistry 1987, 26:6896-6900. PubMed Abstract | Publisher Full Text OpenURL

  33. Nomizu M, Kuratomi Y, Song SY, Ponce ML, Hoffman MP, Powell SK, Miyoshi K, Otaka A, Kleinman HK, Yamada Y: Identification of cell binding sequences in mouse laminin gamma1 chain by systematic peptide screening.

    J Biol Chem 1997, 272:32198-32205. PubMed Abstract | Publisher Full Text OpenURL

  34. Tsilibary EC, Reger LA, Vogel AM, Koliakos GG, Anderson SS, Charonis AS, Alegre JN, Furcht LT: Identification of a multifunctional, cell-binding peptide sequence from the a1(NC1) of type IV collagen.

    J Cell Biol 1990, 111:1583-1591. PubMed Abstract | Publisher Full Text | PubMed Central Full Text OpenURL

  35. Carlisle ES, Mariappan MR, Nelson KD, Thomes BE, Timmons RB, Constantinescu A, Eberhart RC, Bankey PE: Enhancing hepatocyte adhesion by pulsed plasma deposition and polyethylene glycol coupling.

    Tissue Eng 2000, 6:45-52. PubMed Abstract | Publisher Full Text OpenURL

  36. Bhadriraju K, Hansen LK: Hepatocyte adhesion, growth and differentiated function on RGD-containing proteins.

    Biomaterials 2000, 21:267-272. PubMed Abstract | Publisher Full Text OpenURL

  37. Wang S, Nagrath D, Chen PC, Berthiaume F, Yarmush ML: Three-dimensional primary hepatocyte culture in synthetic self-assembling peptide hydrogel.

    Tissue Eng Part A 2008, 14:227-236. PubMed Abstract | Publisher Full Text OpenURL

  38. d'Agostino R, Favia P, Oehr C, Wertheimer MR: Low Temperature Plasma Processing of Materials: Past, Present and Future.

    Plasma Processes and Polymers 2005, 2:7. OpenURL

  39. Palumbo F, Favia P, Vulpio M, d'Agostino R: Plasma Deposition of PEO-like films: diagnostics and process control.

    Plasmas and Polymers 2001, 6:163. Publisher Full Text OpenURL

  40. Sardella E, Gristina R, Senesi GS, d'Agostino R, Favia P: Homogeneous and micro-patterned plasma-deposited PEO-like coatings for biomedical surfaces.

    Plasma Processes and Polymers 2004, 1:63. Publisher Full Text OpenURL

  41. Gristina R, D'Aloia E, Senesi GS, Milella A, Nardulli M, Sardella E, Favia P, d'Agostino R: Increasing cell adhesion on plasma deposited fluorocarbon coatings by changing the surface topography.

    J Biomed Mater Res B Appl Biomater 2009, 88:139-149. PubMed Abstract | Publisher Full Text OpenURL

  42. Sardella E, Detomaso L, Gristina R, Senesi GS, Agheli H, Sutherland DS, d'Agostino R, Favia P: Nano-structured cell-adhesive and cell-repulsive plasma-deposited coatings: chemical and topographical effects on keratinocyte adhesion. Plasma Proc.

    Polym 2008, 5:540. OpenURL

  43. Senesi GS, D'Aloia E, Gristina R, Favia P, d'Agostino R: Surface characterization of plasma deposited nano-structured fluorocarbon coatings for promoting in-vitro cell growth.

    Surface Sicence 2007, 601:1019. Publisher Full Text OpenURL

  44. Salerno S, Piscioneri A, Laera S, Morelli S, Favia P, Bader A, Drioli E, De Bartolo L: Improved functions of human hepatocytes on NH3 plasma-grafted PEEK-WC-PU membranes.

    Biomaterials 2009, 30:4348-4356. PubMed Abstract | Publisher Full Text OpenURL

  45. De Bartolo L, Morelli S, Piscioneri A, Lopez LC, Favia P, d'Agostino R, Drioli E: Novel membranes and surface modification able to activate specific cellular responses.

    Biomol Eng 2007, 24:23-26. PubMed Abstract | Publisher Full Text OpenURL

  46. Lopez LC, Gristina R, Ceccone G, Rossi F, Favia P, d'Agostino R: Immobilization of RGD peptide on stable plasma-deposited acrylic acid coatings for biomedical devices.

    Surface and Coatings Technology 2005, 200:1000. Publisher Full Text OpenURL

  47. De Bartolo L, Morelli S, Rende M, Salerno S, Giorno L, Lopez LC, Favia P, d'Agostino R, Drioli E: Galactose derivative immobilized glow discharge processed polyethersulfone membranes maintain the liver cell metabolic activity.

    J Nanosci Nanotechnol 2006, 6:2344-2353. PubMed Abstract | Publisher Full Text OpenURL

  48. Memoli B, De Bartolo L, Favia P, Morelli S, Lopez LC, Procino A, Barbieri G, Curcio E, Giorno L, Esposito P, Cozzolino M, Brancaccio D, Andreucci VE, d'Agostino R, Drioli E: Fetuin-A gene expression, synthesis and release in primary human hepatocytes cultured in a galactosylated membrane bioreactor.

    Biomaterials 2007, 28:4836-4844. PubMed Abstract | Publisher Full Text OpenURL

  49. Palumbo F, Favia P, Rinaldi A, Vulpio M, d'Agostino RP: PE-CVD of organic thin films with controlled surface concentration of carboxylic groups.

    Plasmas and Polymers 1999, 4:133. Publisher Full Text OpenURL

  50. Detomaso L, Gristina R, d'Agostino R, Senesi GS, Favia P: Plasma deposited acrylic acid coatings: surface characterization and the attachment of 3T3 murine fibroblasts cell lines. Surf. Coat.

    Tech 2005, 200:1022. OpenURL

  51. Detomaso L, Gristina R, Senesi GS, d'Agostino R, Favia P: Stable plasma-deposited acrylic acid surfaces for cell culture applications.

    Biomaterials 2005, 26:3831-3841. PubMed Abstract | Publisher Full Text OpenURL

  52. Mattioli-Belmonte M, Lucarini G, Virgili L, Biagini G, Detomaso L, Favia P, d'Agostino R, Gristina R, Gigante A, Bevilacqua C: Mesenchymal stem cells on plasma-deposited acrylic acid coatings: an in vitro investigation to improve biomaterial performance in bone reconstruction.

    J Bioact Comp Plym 2005, 20:343. Publisher Full Text OpenURL

  53. Francesch L, Borros S, Knoll W, Forch R: Surface reactivity of pulsed-plasma polymerized pentafluorophenyl methacrylate (PFM) toward amines and proteins in solution.

    Langmuir 2007, 23:3927-3931. PubMed Abstract | Publisher Full Text OpenURL

  54. Marí-Buyé N, O'Shaughnessy S, Colominas C, Semino CE, Gleason KK, Borrós S: Functionalized, Swellable Hydrogel Layers as a Platform for Cell Studies.

    Advanced Functional Materials 2009, 19:1276-1286. OpenURL

  55. Morin O, Normand C: Long-term maintenance of hepatocyte functional activity in co-culture: requirements for sinusoidal endothelial cells and dexamethasone.

    J Cell Physiol 1986, 129:103-110. PubMed Abstract | Publisher Full Text OpenURL

  56. Baffet G, Clement B, Glaise D, Guillouzo A, Guguen-Guillouzo C: Hydrocortisone modulates the production of extracellular material and albumin in long-term cocultures of adult rat hepatocytes with other liver epithelial cells.

    Biochem Biophys Res Commun 1982, 109:507-512. PubMed Abstract | Publisher Full Text OpenURL

  57. Johansson S, Hook M: Substrate adhesion of rat hepatocytes: on the mechanism of attachment to fibronectin.

    J Cell Biol 1984, 98:810-817. PubMed Abstract | Publisher Full Text | PubMed Central Full Text OpenURL

  58. Reid LM, Gaitmaitan Z, Arias I, Ponce P, Rojkind M: Long-term cultures of normal rat hepatocytes on liver biomatrix.

    Ann N Y Acad Sci 1980, 349:70-76. PubMed Abstract | Publisher Full Text OpenURL

  59. Li ML, Aggeler J, Farson DA, Hatier C, Hassell J, Bissell MJ: Influence of a reconstituted basement membrane and its components on casein gene expression and secretion in mouse mammary epithelial cells.

    Proc Natl Acad Sci USA 1987, 84:136-140. PubMed Abstract | Publisher Full Text | PubMed Central Full Text OpenURL

  60. De Bartolo L, Morelli S, Lopez LC, Giorno L, Campana C, Salerno S, Rende M, Favia P, Detomaso L, Gristina R, d'Agostino R, Drioli E: Biotransformation and liver-specific functions of human hepatocytes in culture on RGD-immobilized plasma-processed membranes.

    Biomaterials 2005, 26:4432-4441. PubMed Abstract | Publisher Full Text OpenURL

  61. Powers MJ, Janigian DM, Wack KE, Baker CS, Beer SD, Griffith LG: Functional behavior of primary rat liver cells in a three-dimensional perfused microarray bioreactor.

    Tissue Eng 2002, 8:499-513. PubMed Abstract | Publisher Full Text OpenURL

  62. Zhang S, Holmes T, Lockshin C, Rich A: Spontaneous assembly of a self-complementary oligopeptide to form a stable macroscopic membrane.

    Proc Natl Acad Sci USA 1993, 90:3334-3338. PubMed Abstract | Publisher Full Text | PubMed Central Full Text OpenURL