Journal of Atomic, Molecular, and Optical Physics
Volume 2012 (2012), Article ID 948390, 5 pages
Research Article

Silicon-Based Technology for Ligand-Receptor Molecular Identification

1Department of Biochemistry and Medical Biotechnologies, University of Naples “Federico II”, 80131 Naples, Italy
2Institute for Microelectronics and Microsystems, Unit of Naples, National Council of Research, 80131 Naples, Italy
3Department of Clinical and Experimental Medicine, University of “Magna Graecia”, 88100 Catanzaro, Italy
4CEINGE Advanced Biotechnology s.c.a.r.l, 80145 Naples, Italy

Received 23 June 2011; Accepted 4 October 2011

Academic Editor: Ali Hussain Reshak

Copyright © 2012 Annalisa Lamberti et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.


One of the most important goals in the fields of biology and medicine is the possibility to dispose of efficient tools for the characterization of the extraordinary complexity of ligand-receptor interactions. To approach this theme, we explored the use of crystalline silicon (cSi) technology for the realization of a biotechnological device in which the ligand-receptor interactions are revealed by means of optical measurements. Here, we describe a chemical procedure for the functionalization of microwell etched on silicon wafers, and the subsequent anchoring of biological molecules like an antibody anti-A20 murine lymphoma cell line. The optical analysis of the interaction on the biochips between the bound biomolecule and their corresponding ligand indicated that the functionalized cSi is suitable for this application.

1. Introduction

Circulating tumor cells (CTCs) are emerging as a powerful prognostic and predictive biomarker in several types of cancer, including breast, colon, and prostate. However, studies of CTCs in metastasis and further development of CTCs as a biomarker in cancer have been hampered by the low concentration of CTCs in peripheral blood and by the inherent difficulties to recover CTCs from blood of patients. For this reason, it is compelling to implement novel devices and procedures to improve isolation rate and in vitro expansion of CTCs. Moreover, the extraordinary complexity of ligand-receptor interaction limits our knowledge of the molecular mechanisms of tumorigenesis and is a major obstacle in developing cancer-specific therapeutic agents. Pioneer studies of protein complexes have revealed that a given protein can physically associate to tens (>200) of different proteins [1]. In the case of eukaryotic cells, 20,000 proteins or more may establish an extraordinary large number of functional interactions with cell receptors, making unrealistic a systematic approach where each ligand-receptor interaction is studied as a single network. To overcome these hurdles, we recently dedicated to a comprehensive analysis of ligand-receptor interactions in mammalian cells [2, 3] developing a novel biochip based on the chemical and optical properties of porous silicon [4] where the ligand-receptor interaction is transduced, at high levels of specificity and sensitivity, in an optical signal generated by change of pSI refractive index [57]. Here, we propose to develop a device based on crystalline silicon that combines analytic and preparative properties to improve speed and efficiency of isolation of CTCs from blood of patients affected by cancer. This will lead to the development of basic diagnostic kits that will be of help in the diagnosis of cancer and/or to the discovery of novel markers of pharmaceutical resistance as well as the identification of new target agents for treatment of cancer. The strategy includes the chemical functionalization of the silicon surface by using bifunctional linker molecules; the anchoring to the functionalized surface of specific antibodies; the assay of the biochip activity by evaluating its ability to reveal the corresponding antibody-ligand interaction.

2. Experimental

Silicon microwell array preparation. A siliconnitride film was obtained by plasma enhancedchemical vapor deposition on p+-silicon wafer, 1 0 0 oriented; 400 μm thick. A standard photolithographic process to pattern the silicon nitride film was used; the etching of the silicon nitride was performed by (reactive ion etching) RIE process in CHF3/O2 atmosphere followed by local electrochemical etching of silicon in a hydrofluoric acid-water solution (50 : 50, v/v), photoresist removal by acetone, and anisotropic treatment in KOH (KOH/H2O, 1 : 2, w/w) of crystalline silicon (for microwell formation) for 120 minutes at 80°C under stirring. Removal of the siliconnitride was done in HF/H2O (1 : 10) for 20 sec. The quality of silicon nitride layer was checked by ellipsometry in order to evaluate the thickness, roughness, and refractive index. The silicon nitride resulted 410 nm thick with a roughness of about 5 nm.

Microwell functionalization. The microwells werefunctionalized according the following procedure. Microwells were thermal oxidized in O2 atmosphere at 900°C for 15 minutes and subsequently treated in a piranha solution (sulphuric acid/H2O2, 4 : 1) at room temperature (RT) for 40 minutes in order to activate the formation of -OH groups on the wafer surface. After extensive washes with distilled water and drying under N2, wafers were treated with a solution of 5% APTES, (3-Aminopropyl) triethoxysilane (Sigma) in toluene for 30 minutes at RT, washed with toluene twice, curing on heater at 100°C for 10 minutes, and washed again with toluene twice. The wafers were then treated at RT for 30 minutes with a glutaraldehyde (GA) in 20 mM HEPES (4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid), pH 7.5, and washed three times (3 × 5 minutes) in 20 mM HEPES, pH 7.5. Subsequently, the microwells were incubated at 4°C overnight in the presence of protein A (PA) (2 mg/mL, final concentration) in 20 mM HEPES, pH 8.0 (10 μL of PA solution for each well). Finally, after three washes of the microwells at RT with 20 mM HEPES, pH 8.0 (3 × 5 minutes) the devices were incubated overnight at 4°C with an antibody anti-IgG 6.6 μM in 1x phosphate buffer saline (PBS). Lastly, after three washes (3 × 5 minutes) at RT, the microwells were ready for experimental tests.

3. Results and Discussion

Figure 1 shows the photolithographic mask of 12 crystalline silicon microwells. The scanning electron microscopy (SEM) image of the microwell showed that microwells were about 5.7 μL (0.69 cm × 0.69 cm × 120 μm). Moreover, the SEM image enlargements highlighted the isotropic formation of the microchamber. The microwells were functionalized according to the chemical reaction steps schematically reported in Figure 2. In order to check the efficiency of each reaction, we evaluated the presence of the chemical layer by ellipsometric measurements. As reported in Table 1, using a random sampling of 4 different wells, it was observed for all of them after each functionalization step almost the same chemical properties. This procedure was also followed by FT-IR spectromicroscopy performed with a Nicolet 5700 equipped with a microscope Continuμm, settled with a 50 × 50 μm window, sensitivity 8, and 200 acquisition/minute (Figure 3). The analyses of the FT-IR spectra led to the identification of several characteristic vibration bands that were coherent with the various functionalization steps. Table 2 reports a list of the major bands identified together to peak assignment.

Table 1: Ellipsometric measurements of the surface layer thickness after each reaction step.
Table 2: Frequencies (cm−1) of major infrared bands observed in wafer samples and peak assignment.
Figure 1: Microwells wafer images. (a) 12 microwells photolithographic mask. (b) SEM image of a microwell with the enlargement showing the isotropic formation.
Figure 2: Functionalization steps of the crystalline silicon. (a) Oxidation and activation of -OH groups. (b) Reaction with bifunctional GA linker. (c) Binding of protein A to GA. (d) Functionalized microwell ready for the binding to IgG.
Figure 3: FT-IR spectra of the crystalline silicon (cSi) wafers after the functionalization steps. (a) cSi. (b) cSi after thermal oxidation. (c) cSi after APTES. (d) cSi after GA. (e) cSi after PA. (f) cSi after IgG.

We next explored the application of the functionalized biochip to function as possible array for the binding and identification of cell lines. As on experimental model, it was chosen a murine lymphoma cell line (A20) [8]. These cells express high levels of membrane IgG. For this purpose, antibody antimembrane immunoglobulin was bound to the functionalized biochip as previously described. The biochip was then incubated in the presence of A20 cells at a concentration of 5 × 106 cells/mL in 1x PBS at RT for 2 hours. After several washes in 1x PBS, the wafers were analyzed under a light microscope (Leika DM6000M). As negative control, it was used a microwell that was incubated with a cell line not expressing membrane IgG (CB1) and abiochip lacking the antibody anti-IgG. As shown in Figure 4, the IgG-functionalized microwell was able to bind specifically the A20 cells (Figures 4(a) and 4(b)) whereas it did not recognize different cells (Figure 4(c)). In addition, A20 cells were not able to bind to the biochip lacking antibody anti-IgG (Figure 4(d)).

Figure 4: Binding of A20 cells to the functionalized silicon wafer. Images from optical microscope (20x enlargement) of the biochip functionalized with antibody anti-IgG (6,8 μM) and then incubated with A20 cells before washes (a) and after washes (b). Optical image after washes of the biochip functionalized with anti-IgG and incubated with CB1 cells (c). Optical image after washes of the biochip lacking anti-IgG and incubated with A20 cells (d).

4. Conclusions

In this experimental work, we explored the use of the crystalline silicon technology in order to construct a biochip that allows the identification of specific ligand-receptor interactions. The microfabricated biochips appear to be suitable to reveal specific bindings such as that between cell surface proteins (receptor) and corresponding specific antibody. The results obtained represent an encouraging starting point for the application of this specific technology to develop a lab-on-chip microarray system for the specific recognition circulating tumor cells (CTCs). Moreover, the versatility of the engineered biochip could be useful to reveal other several specific bindings such as that between an antibody and its ligand peptide. Furthermore, this biochip can be useful to find and characterize new specific receptor-ligand interactions through the screening of a recombinant phage library.


The work described was financed by MIUR (Rome), FIRB 2003, Contract no. RBLA033WJX_003.


  1. A. C. Gavin, M. Bösche, R. Krause et al., “Functional organization of the yeast proteome by systematic analysis of protein complexes,” Nature, vol. 415, no. 6868, pp. 141–147, 2002. View at Publisher · View at Google Scholar · View at Scopus
  2. G. Scala, X. Chen, W. Liu et al., “Selection of HIV-specific immunogenic epitopes by screening random peptide libraries with HIV-1-positive sera,” Journal of Immunology, vol. 162, no. 10, pp. 6155–6161, 1999. View at Google Scholar · View at Scopus
  3. P. De Berardinis, R. Sartorius, C. Fanutti, R. N. Perham, G. Del Pozzo, and J. Guardiola, “Phage display of peptide epitopes from HIV-1 elicits strong cytolytic responses,” Nature Biotechnology, vol. 18, no. 8, pp. 873–876, 2000. View at Publisher · View at Google Scholar · View at Scopus
  4. L. De Stefano, L. Moretti, A. Lamberti et al., “Optical sensors for vapors, liquids, and biological molecules based on porous silicon technology,” IEEE Transactions on Nanotechnology, vol. 3, no. 1, pp. 49–54, 2004. View at Publisher · View at Google Scholar · View at Scopus
  5. L. De Stefano, L. Rotiroti, I. Rea et al., “Porous silicon-based optical biochips,” Journal of Optics A, vol. 8, no. 7, pp. S540–S544, 2006. View at Publisher · View at Google Scholar · View at Scopus
  6. L. De Stefano, P. Arcari, A. Lamberti et al., “DNA optical detection based on porous silicon technology: from biosensors to biochips,” Sensors, vol. 7, no. 2, pp. 214–221, 2007. View at Google Scholar · View at Scopus
  7. E. De Tommasi, L. De Stefano, I. Rea et al., “Porous silicon based resonant mirrors for biochemical sensing,” Sensors, vol. 8, no. 10, pp. 6549–6556, 2008. View at Publisher · View at Google Scholar · View at Scopus
  8. L. H. Glimcher, K. J. Kim, I. Green, and W. E. Paul, “Ia antigen-bearing B cell tumor lines can present protein antigen and alloantigen in a major histocompatibility complex-restricted fashion to antigen-reactive T cells,” Journal of Experimental Medicine, vol. 155, no. 2, pp. 445–459, 1982. View at Google Scholar · View at Scopus