Perforation Does Not Compromise Patterned Two-Dimensional

Sep 28, 2017 - Polymeric sheets were perforated by laser ablation and were uncompromised by a debris field when first treated with a thin layer of pho...
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Letter pubs.acs.org/journal/abseba

Perforation Does Not Compromise Patterned Two-Dimensional Substrates for Cell Attachment and Aligned Spreading Stephen B. Bandini,⊥,† Joshua A. Spechler,⊥,‡ Patrick E. Donnelly,⊥,† Kelly Lim,⊥,† Craig B. Arnold,‡ Jean E. Schwarzbauer,§ and Jeffrey Schwartz*,† †

Department of Chemistry, ‡Department of Mechanical and Aerospace Engineering, §Department of Molecular Biology, Princeton University, Princeton, New Jersey 08544, United States S Supporting Information *

ABSTRACT: Polymeric sheets were perforated by laser ablation and were uncompromised by a debris field when first treated with a thin layer of photoresist. Polymer sheets perforated with holes comprising 5, 10, and 20% of the nominal surface area were then patterned in stripes by photolithography, which was followed by synthesis in exposed regions of a cell-attractive zirconium oxide-1,4-butanediphosphonic acid interface. Microscopic and scanning electron microscopy analyses following removal of unexposed photoresist show well-aligned stripes for all levels of these perforations. NIH 3T3 fibroblasts plated on each of these perforated surfaces attached to the interface and spread in alignment with pattern fidelity in every case that is as high as that measured on a nonperforated, patterned substrate. KEYWORDS: polymer laser ablation, perforated substrate, two-dimensional patterned cell alignment

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ation of plated cells in register with the chemical pattern; cell proliferation is unconstrained and remains aligned over the entire surface,22 and cell-assembled ECM is also in register with the ZrO2−phosphonate pattern.23 Stacking such sheets in a 3D construct could, however, be unfavorable for cell viability in the depths of the device: lateral transport of oxygen and nutrients from the device periphery to cells growing toward its center, and removal of waste products from it, could be limiting.24,25 It is well-established that perforation facilitates transport in biological26−33 and engineered34−38 systems. Therefore, were perforations to be present in each 2D-patterned layer of a 3D construct, transport of nutrients and waste products throughout the device would be facilitated, yet these very holes could compromise our cell templating approach. Here, we show that films of polyetherether ketone (PEEK) can be perforated systematically to 20% of their nominal surface areas by laser ablation and that such perforations do not compromise controlled patterning with a cell-adhesive ZrO2−phosphonate interface.39 Furthermore, we show that these surfaces template cell spreading with spatial alignment control as strong as that achieved using nonperforated surfaces.23

challenge for tissue engineering is to direct cell organization in a three-dimensional (3D) device;1 an ideal device should induce cells to adopt the specific, native-like organization characteristic of a particular tissue type that is required for proper function.2−5Among such scaffold models are 3D printed structures, hydrogels, porous foams, and exogenous extracellular matrix (ECM).6−8 These scaffold classes have been constructed artfully using synthetic or natural materials to incorporate, for example, growth factors or cellattachment peptides to improve bioactivity; others have been designed to incorporate microfluidic channels to mimic vascularization.9,10 Several of these have shown clinical promise for tissue repair.11 Templating spatially aligned cell growth in a 3D construct that leads to similarly aligned ECM might provide the basis for a scaffold model to recapitulate native tissue properties.12 3D printing occurs, effectively, through layer-bylayer two-dimensional (2D) printing;13−16 3D constructs can thus be envisaged as a stack of 2D patterned sheets in which spatially controlling cell spreading on their surfaces is key.17−21 Our method to accomplish aligned cell spreading and ECM assembly was demonstrated on a range of biomaterial polymers. It involves patterning with a cell-attractive, two-component interface consisting of micrometer-dimension stripes of a zirconium oxide (ZrO2) layer that is terminated with a selfassembled monolayer of an α,ω-diphosphonate (SAMP). This nanometer-thin construct templates attachment and prolifer© XXXX American Chemical Society

Received: May 30, 2017 Accepted: September 28, 2017 Published: September 28, 2017 A

DOI: 10.1021/acsbiomaterials.7b00339 ACS Biomater. Sci. Eng. XXXX, XXX, XXX−XXX

Letter

ACS Biomaterials Science & Engineering

Figure 1. Protection scheme for laser ablation of PEEK films. (A) Perforations are introduced by laser ablation without a photoresist cover layer; after sonication in ethanol, a large debris field remains around the ablated hole. (B) With photoresist protection, debris lands on the photoresist layer, and sonication in ethanol yields a well-defined hole with minimal debris surrounding it. Optical images; scale bar = 40 μm.

Figure 2. Optical images of perforated PEEK substrates with (A) 5% surface coverage by holes, (B) 10% coverage via “head-to-tail” ablation, (C) 10% coverage by “side-to-side” ablation, and (D) 20% coverage. Each surface was functionalized with the ZrO2−phosphonate interface patterned in 30 × 30 μm stripes; scale bar = 100 μm. A SEM image shows well-defined patterning around the laser-ablated perforation (E), and the EDX maps of ZrLα1 (F) and PKα1 (G) confirm that the ZrO2−phosphonate modification conforms to the pattern.

when photoresist AZ-5214-E was spin-cast on both sides of the PEEK coupons and then heated (95 °C) to cure, debris from ablation procedure landed on top of the photoresist; removal by sonication in ethanol showed the formation of well-defined perforations that were surrounded by clean polymer (Figure 1B). Perforations 130 × 30 μm were chosen to be large enough to prevent blockage by a single cell;42 perforations on PEEK surfaces were introduced in several patterns such that the distance from an attached cell to any hole would be no more than 200 μm, the estimated maximum distance that oxygen diffuses from a capillary to support metabolically active tissue.43 We prepared substrates in which 5, 10, and 20% of their nominal surface areas consisted of holes to test the limits of our patterning procedures. Doubling the number of holes to convert 5% nominal surface coverage to 10% was done either “head to tail” (Figure 2B) or “side to side” (Figure 2C); surfaces with 20% nominal hole coverage were created by

In a typical experiment, a 355 nm diode pumped, solid state pulsed Nd:YVO4 laser was used to perforate 50 μm-thick PEEK films. The laser beam was focused to a diameter ca. 8 μm at an energy ca. 40 μJ, yielding a fluence of ca. 80 J/cm2, which is in accord with published values for the ablation threshold and hole depth for PEEK films ablated by a 308 nm XeCl eximer pulsed laser;40,41 it was adequate to cut through the PEEK with one pass. The laser pulsed every 1 μm while tracing out the perforations, and the stages moved at a speed of 10 mm/s, giving a laser repetition rate of 10 kHz. Initial attempts at ablating clean 1 × 1 cm PEEK substrates showed that the perforation process yielded a debris field that could be visualized by optical microscopy as large, dark areas surrounding the ablated holes (Figure 1A); sonication in ethanol did not remove the debris. This problem was obviated through the simple expedient of first coating the polymer coupons with the same photoresist that was used subsequently for surface photolithographic patterning (Figure 1B). Thus, B

DOI: 10.1021/acsbiomaterials.7b00339 ACS Biomater. Sci. Eng. XXXX, XXX, XXX−XXX

Letter

ACS Biomaterials Science & Engineering

Figure 3. Top row: Representative images of actin stained NIH 3T3 fibroblasts grown on patterns of the ZrO2−phosphonate on perforated PEEK substrates after 3 days: (A) nonperforated PEEK, reproduced with permission from ref 22, copyright 2013, the Royal Society of Chemistry; (B) 5% nominal surface coverage by holes; (C) 10% coverage via the head-to-tail ablation scheme or (D) by the side-to-side ablation scheme; (E) 20% coverage. Pattern direction is in the direction of the red arrow on each substrate; magnification 10×, scale bar = 100 μm. Bottom row: Representative FFT outputs of actin images for each of the above surfaces. FFT outputs are shown with red lines though each oval to measure the aspect ratio, which is indicated at the bottom as average ±1 standard deviation; the lower the number, the better the alignment. See also Supporting Information, Figure 2 for an image taken at 7 days on a substrate with 5% nominal surface coverage by holes.

EDX data are supportive of the assignments made here (Supporting Information, Figure 1). NIH 3T3 fibroblasts were plated on ZrO2−phosphonatepatterned PEEK substrates with 5, 10, and 20% nominal surface hole coverages to determine if perforation adversely affected cell attachment and spreading in alignment with the pattern. Cells were plated at 30 000 cells/1 cm2 of nominal substrate surface in DMEM with 10% bovine calf serum19 and were grown for 3 days before being fixed with 3.7% formaldehyde in phosphate-buffered saline, permeabilized with NP-40, and stained with rhodamine−phalloidin to visualize actin filaments. Analysis showed that the cells had spread around and between, but not over, the holes and were in alignment with the ZrO2− phosphonate pattern (Figure 3). Actin was found to be aligned over the surfaces in register with the patterns after cells had reached confluence (Supporting Figure 1). Quantitatively comparing cell alignment on patterned, nonperforated versus patterned, perforated surfaces was done by measuring aspect ratios of Fast Fourier Transform (FFT) outputs from stained actin images of adhered cells (Figure 3).22 FFT analysis was done on four 10× images each a perfect square of 1024 × 1024 pixels. Image contrast was normalized with pixel saturation set at 0.4%; FFT was determined using ImageJ software in which grayscale output was colorized using the “spectrum” table. We define the aspect ratio by dividing the width of the FFT output oval by its length; thus, the smaller the aspect ratio, the better the alignment. This ratio was 0.69 ± 0.09 for cells on patterned, nonperforated PEEK (Figure 3A); patterned, perforated substrates had ratios of 0.53 ± 0.05, 0.59 ± 0.09, 0.62 ± 0.09, and 0.59 ± 0.03 for cells on surfaces with 5% hole coverage (Figure 3B), 10% hole coverage via head-totail ablation (Figure 3C), 10% hole coverage via side-to-side ablation (Figure 3D), and 20% hole coverage (Figure 3E), respectively. These data show that the cells are at least as wellaligned on patterned, perforated PEEK as they are on patterned, nonperforated PEEK; this conclusion is further

doubling these numbers of ablations. Photolithography by spincoating photoresist on heavily perforated surfaces has not been reported, and a minor complication was that perforated PEEK did not attach to the spin coater chuck as is necessary to deposit photoresist: the holes obviate a vacuum seal between it and the chuck of the spin coater. This was easily addressed by first adhering the perforated polymer to a glass slide using several drops of uncured photoresist; the PEEK/glass ensemble was then spin-coated with additional photoresist at 4000 rpm for 40 s, then baked at 95 °C for 45 s. The ensembles were exposed to UV (365 nm, 4W) through a photomask for 40 s to create 30 μm wide stripes separated by 30 μm (30 × 30 μm); in each case patterned stripes of the photomask were oriented parallel to the perforated holes. Treating with AZ MIF 300 developer for 35 s gave oriented, striated patterns on the perforated PEEK (Figure 2). The ensembles were then exposed to vapor of zirconium tetra(tert-butoxide) (1) for 5 min at 10−3 Torr; oxygen-containing functionalities of the PEEK enable its coordinative bonding to 1.39 Heating to 65 °C gave a surfacebound, cross-linked, mixed zirconium oxide/tert-butoxide pattern, which was converted to patterned ZrO2−phosphonate by immersion in a solution of 1,4-butanediphosphonic acid in ethanol (0.25 mg/mL);22 this ethanol treatment also removed residual photoresist. Optical microscopy showed the patterned regions to be parallel with the ablated holes; both holes and patterns were uniform over the entire PEEK surface, with hole coverage of 5, 10, and 20% of the substrates nominal areas (Figures 2A−E). Apparently, even when 20% of the surface has been ablated away, the substrate could still be spin-coated with an adequate layer of photoresist in both uniformity and thickness for photolithographic patterning. EDX analysis (Figure 2F−G) confirmed the composition of these patterns to be the desired ZrO2−phosphonate. Because the ZrO2 interface is only about 1 nm-thick and its phosphonate termination is a monolayer,39 EDX signals for Zr and P are weak and difficult to distinguish from background; line scans of C

DOI: 10.1021/acsbiomaterials.7b00339 ACS Biomater. Sci. Eng. XXXX, XXX, XXX−XXX

ACS Biomaterials Science & Engineering



supported by ANOVA (α = 0.05), where no statistical difference was found for the aspect ratio among all of the PEEK surfaces (p = 0.114). It is not known to what extent, if any, the presence of holes affects the FFT output, although there is no apparent correlation between hole number or alignment with measured aspect ratios. We showed that clean perforation of a surface-protected polymer film can be accomplished by laser ablation and that this material can be patterned to template spatially controlled cell spreading in a way that is as effective as on unperforated polymer substrates. Protecting PEEK with a thin layer of photoresist prior to laser treatment causes all debris from ablation to be deposited on top of this layer, which is then removed by sonication in ethanol. Ablation-perforated PEEK is easily patterned by photolithography to prepare cell-adhesive ZrO2−phosphonate striations; patterned PEEK films template cell spreading in alignment with these striations, even when perforations account for 20% of the nominal surface area. Given the ease of implementing our methods, our procedures for material transformation might provide an effective approach to envisaged 3D constructs based on stacked 2D-patterned, perforated polymer sheets that would be designed also to obviate layer-to-layer compression. Coupled with demonstrated excellence in spatially determined surface chemical modification of polymer films and of ECM assembly on them,23 these methods may help inform new routes for fabricating tissue scaffolds comprising cell-assembled matrix44 or organ-on-a-chip technologies45 that effectively recapitulate native tissue architectures in which biodegradable polymeric substrates can be accommodated.



REFERENCES

(1) Andersson, H.; van den Berg, A. Microfabrication and microfluidics for tissue engineering: state of the art and future opportunities. Lab Chip 2004, 4, 98−103. (2) Sasaki, K.; Yamamoto, N.; Kiyosawa, T.; Sekido, M. The role of collagen arrangement change during tendon healing demonstrated by scanning electron microscopy. J. Electron Microsc. 2012, 61, 327−334. (3) Kim, D.-H.; Lipke, E. A.; Kim, P.; Cheong, R.; Thompson, S.; Delannoy, M.; Suh, K.-Y.; Tung, L.; Levchenko, A. Nanoscale cues regulate the structure and function of macroscopic cardiac tissue constructs. Proc. Natl. Acad. Sci. U. S. A. 2010, 107, 565−570. (4) Huber, A. B.; Kolodkin, A. L.; Ginty, D. D.; Cloutier, J.-F. Signaling at the growth cone: Ligand-Receptor Complexes and the Control of Axon Growth and Guidance. Annu. Rev. Neurosci. 2003, 26, 509−563. (5) Hassell, J. R.; Birk, D. E. The molecular basis of corneal transparency. Exp. Eye Res. 2010, 91, 326−335. (6) Lee, K. Y.; Mooney, D. J. Hydrogels for Tissue Engineering. Chem. Rev. 2001, 101, 1869−1880. (7) De Mulder, E. L. W.; Buma, P.; Hannink, G. Anisotropic Porous Biodegradable Scaffolds for Musculoskeletal Tissue Engineering. Materials 2009, 2, 1674−1696. (8) Song, J. J.; Ott, H. C. Organ engineering based on decellularized matrix scaffolds. Trends Mol. Med. 2011, 17, 424−432. (9) Khademhosseini, A.; Langer, R. Microengineered hydrogels for tissue engineering. Biomaterials 2007, 28, 5087−5092. (10) Miller, J. S.; Stevens, K. R.; Yang, M. T.; Baker, B. M.; Nguyen, D.-H. T.; Cohen, D. M.; Toro, E.; Chen, A. A.; Galie, P. A.; Yu, X.; Chaturvedi, R.; Bhatia, S. N.; Chen, C. S. Rapid casting of patterned vascular networks for perfusable engineered three-dimensional tissues. Nat. Mater. 2012, 11, 768−774. (11) Sicari, B. M.; Rubin, J. P.; Dearth, C. L.; Wolf, M. T.; Ambrosio, F.; Boninger, M.; Turner, N. J.; Weber, D. J.; Simpson, T. W.; Wyse, A.; Brown, E. H. P.; Dziki, J. L.; Fisher, L. E.; Brown, S.; Badylak, S. F. An Acellular Biologic Scaffold Promotes Skeletal Muscle Formation in Mice and Humans with Volumetric Muscle Loss. Sci. Transl. Med. 2014, 6, 234ra258. (12) Dvir, T.; Timko, B. P.; Kohane, D. S.; Langer, R. Nanotechnological strategies for engineering complex tissues. Nat. Nanotechnol. 2011, 6, 13−22. (13) Khademhosseini, A.; Langer, R.; Borenstein, J.; Vacanti, J. P. Microscale technologies for tissue engineering and biology. Proc. Natl. Acad. Sci. U. S. A. 2006, 103, 2480−2487. (14) Ohashi, K.; Yokoyama, T.; Yamato, M.; Kuge, H.; Kanehiro, H.; Tsutsumi, M.; Amanuma, T.; Iwata, H.; Yang, J.; Okano, T.; Nakajima, Y. Engineering functional two- and three-dimensional liver systems in vivo using hepatic tissue sheets. Nat. Med. 2007, 13, 880−885. (15) Yuan, B.; Jin, Y.; Sun, Y.; Wang, D.; Sun, J.; Wang, Z.; Zhang, W.; Jiang, X. A Strategy for Depositing Different Types of Cells in Three Dimensions to Mimic Tubular Structures in Tissues. Adv. Mater. 2012, 24, 890−896. (16) Mata, A.; Kim, E. J.; Boehm, C. A.; Fleischman, A. J.; Muschler, G. F.; Roy, S. A three-dimensional scaffold with precise microarchitecture and surface micro-textures. Biomaterials 2009, 30, 4610− 4617. (17) Kane, R. S.; Takayama, S.; Ostuni, E.; Ingber, D. E.; Whitesides, G. M. Patterning proteins and cells using soft lithography. Biomaterials 1999, 20, 2363−2376. (18) Jeon, H.; Simon, C. G.; Kim, G. A mini-review: Cell response to microscale, nanoscale, and hierarchical patterning of surface structure. J. Biomed. Mater. Res., Part B 2014, 102, 1580−1594. (19) Guillotin, B.; Guillemot, F. Cell patterning technologies for organotypic tissue fabrication. Trends Biotechnol. 2011, 29, 183−190. (20) Khan, S.; Newaz, G. A comprehensive review of surface modification for neural cell adhesion and patterning. J. Biomed. Mater. Res., Part A 2010, 93A, 1209−1224. (21) Goubko, C. A.; Cao, X. Patterning multiple cell types in cocultures: A review. Mater. Sci. Eng., C 2009, 29, 1855−1868.

ASSOCIATED CONTENT

S Supporting Information *

The Supporting Information is available free of charge on the ACS Publications website at DOI: 10.1021/acsbiomaterials.7b00339.



Letter

Image of confluent layer of cells on a 5% perforated substrate at 7 days (PDF)

AUTHOR INFORMATION

Corresponding Author

*E-mail: [email protected]. ORCID

Jeffrey Schwartz: 0000-0001-9873-4499 Author Contributions ⊥

The manuscript was written through contributions of all authors. All authors have given approval to the final version of the manuscript. S.B.B., J.A.S., P.E.D., and K.L. contributed equally. Notes

The authors declare no competing financial interest.



ACKNOWLEDGMENTS The authors thank the National Science Foundation Princeton MRSEC (Grant DMR-1420541), the Princeton Institute for the Science and Technology of Materials, and the National Institutes of Health (Grant R01 CA160611 to J.E.S.). D

DOI: 10.1021/acsbiomaterials.7b00339 ACS Biomater. Sci. Eng. XXXX, XXX, XXX−XXX

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ACS Biomaterials Science & Engineering (22) Donnelly, P. E.; Jones, C. M.; Bandini, S. B.; Singh, S.; Schwartz, J.; Schwarzbauer, J. E. A simple nanoscale interface directs alignment of a confluent cell layer on oxide and polymer surfaces. J. Mater. Chem. B 2013, 1, 3553−3561. (23) Singh, S.; Bandini, S. B.; Donnelly, P. E.; Schwartz, J.; Schwarzbauer, J. E. A cell-assembled, spatially aligned extracellular matrix to promote directed tissue development. J. Mater. Chem. B 2014, 2, 1449−1453. (24) Tsang, V.; Bhatia, S. N. Three-dimensional tissue fabrication. Adv. Drug Delivery Rev. 2004, 56, 1635−1647. (25) Papenburg, B. J.; Liu, J.; Higuera, G. A.; Barradas, A. M. C.; de Boer, J.; van Blitterswijk, C. A.; Wessling, M.; Stamatialis, D. Development and analysis of multi-layer scaffolds for tissue engineering. Biomaterials 2009, 30, 6228−6239. (26) Kelso, C. M.; Watanabe, H.; Wazen, J. M.; Bucher, T.; Qian, B. S.; Olson, E. A.; Kysar, J. W.; Lalwani, A. K. Microperforations Significantly Enhance Diffusion Across Round Window Membrane. Otol. Neurotol. 2015, 36, 694−700. (27) Egert, U.; Okujeni, S.; Nisch, W.; Boven, K.-H.; Rudorf, R.; Gottschlich, N.; Stett, A. In Mikrosystemtechnik-Kongress 2005:10. bis 12. Oktober 2005 in Freiburg; Zengerle, R., Ed.; Margret Schneider: Freiburg, Germany, 2005; pp 427−430. (28) Killian, N. J.; Vernekar, V. N.; Potter, S. M.; Vukasinovic, J. A Device for Long-Term Perfusion, Imaging, and Electrical Interfacing of Brain Tissue In vitro. Front. Neurosci. 2016, DOI: 10.3389/ fnins.2016.00135. (29) Rambani, K.; Vukasinovic, J.; Glezer, A.; Potter, S. M. Culturing thick brain slices: An interstitial 3D microperfusion system for enhanced viability. J. Neurosci. Methods 2009, 180, 243−254. (30) Heiduschka, P.; Romann, I.; Stieglitz, T.; Thanos, S. Perforated Microelectrode Arrays Implanted in the Regenerating Adult Central Nervous System. Exp. Neurol. 2001, 171, 1−10. (31) Yang, F.; Yang, C.-H.; Wang, F.-M.; Cheng, Y.-T.; Teng, C.-C.; Lee, L.-J.; Yang, C.-H.; Fan, L.-S. A high-density microelectrode-tissuemicroelectrode sandwich platform for application of retinal circuit study. BioMed. Eng. OnLine 2015, 14, 1 DOI: 10.1186/s12938-0150106-5. (32) Reinhard, K.; Tikidji-Hamburyan, A.; Seitter, H.; Idrees, S.; Mutter, M.; Benkner, A.; Münch, T. A. Step-By-Step Instructions for Retina Recordings with Perforated Multi Electrode Arrays. PLoS One 2014, 9, e106148. (33) Boppart, S. A.; Wheeler, B. C.; Wallace, C. S. A Flexible Perforated Microelectrode Array for Extended Neural Recordings. IEEE Trans. Biomed. Eng. 1992, 39, 37−42. (34) Manahan, M. P.; Mench, M. M. Laser Perforated Fuel Cell Diffusion Media: Engineered Interfaces for Improved Ionic and Oxygen Transport. J. Electrochem. Soc. 2012, 159, F322−F330. (35) Dennison, C. R.; Agar, E.; Akuzum, B.; Kumbur, E. C. Enhancing Mass Transport in Redox Flow Batteries by Tailoring Flow Field and Electrode Design. J. Electrochem. Soc. 2016, 163, A5163− A5169. (36) Nishida, K.; Kono, Y.; Sato, M.; Mizuguchi, D. Acceleration of Liquid Water Removal from Cathode Electrode of PEFC By Combination of Channel Hydrophilization and Diffusion Medium Perforation. ECS Trans. 2016, 75, 227−236. (37) Mayrhuber, I.; Dennison, C. R.; Kalra, V.; Kumbur, E. C. Laserperforated carbon paper electrodes for improved mass transport in high power density vanadium redox flow batteries. J. Power Sources 2014, 260, 251−258. (38) Gerteisen, D.; Sadeler, C. Stability and performance improvement of a polymer electrolyte membrane fuel cell stack by laser perforation of gas diffusion layers. J. Power Sources 2010, 195, 5252− 5257. (39) Dennes, T. J.; Schwartz, J. A Nanoscale Adhesion Layer to Promote Cell Attachment on PEEK. J. Am. Chem. Soc. 2009, 131, 3456−3457. (40) Dyer, P. E.; Oldershaw, G. A.; Schudel, D. XeCl laser ablation of polyetheretherketone. Appl. Phys. B: Photophys. Laser Chem. 1990, 51, 314−316.

(41) Babu, S. V.; D’Couto, G. C.; Egitto, F. D. Excimer laser induced ablation of polyetheretherketone, polyimide, and polytetrafluoroethylene. J. Appl. Phys. 1992, 72, 692−698. (42) Santos, E.; Hernandez, R. M.; Pedraz, J. L.; Orive, G. Novel advances in the design of three-dimensional bio-scaffolds to control cell fate: translation from 2D to 3D. Trends Biotechnol. 2012, 30, 331− 341. (43) Muschler, G. F.; Nakamoto, C.; Griffith, L. G. Engineering Principles of Clinical Cell-Based Tissue Engineering. J. Bone Joint Surg. 2004, 86, 1541−1558. (44) Daley, W. P.; Peters, S. B.; Larsen, M. Extracellular matrix dynamics in development and regenerative medicine. J. Cell Sci. 2008, 121, 255−264. (45) Bhatia, S. N.; Ingber, D. E. Microfluidic organs-on-chips. Nat. Biotechnol. 2014, 32, 760−772.

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DOI: 10.1021/acsbiomaterials.7b00339 ACS Biomater. Sci. Eng. XXXX, XXX, XXX−XXX