DESIGN AND OPTIMIZATION OF QCM BIOSENSOR TO DETECT MALIGNANT MELANOMA CELLS VIA THEIR CD44 RECEPTORS
Date
2024Author
SAMEER AIOSH, Rahaf
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Malignant melanoma (MM) is a highly aggressive form of skin cancer originating from
melanocytes, presents a significant public health concern globally. Its rising incidence
and propensity for metastasis underscore the critical need for innovative diagnostic
approaches to enable early detection and intervention. In this study, we address this
pressing issue by proposing the design and optimization of a quartz crystal equilibrium
(QCM) biosensor capable of detecting MM cells through CD44 (cluster of differentiation
44) receptors. Which is very highly expressed on the surfaces of MM cells. We aimed to
identify these cells by combining QCM with the CD44-binding antibody DF6392. In the
first step, to enhance the QCM chip's surface area, nanoparticles were synthesized through
a miniemulsion polymerization process involving (EDGMA) ethylene
glycoldimethacrylate and (HEMA) 2-hydroxyethyl methacrylate. The nanoparticles
underwent characterization using zeta-sizer measurements. Prior to applying the polymer
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onto the QCM chip, additional modification and activation of the surface were carried
out. Initially, QCM chip underwent surface modification with 11-mercaptoundecanoic
acid (MUA) to enable polymer binding. N-hydroxysuccinimide (NHS) and ethyl-3-(3-
dimethylaminopropyl) carbodiimide (EDC) were employed for activation purposes. The
functionalization of poly(2-hydroxyethyl methacrylate) nanoparticles (P(HEMA-NPs))
was conducted using (APTES) (3-aminopropyltriethoxy silane) in order to replace the
polymer's hydroxyl group with a nitrogen group to bind to the existing carboxyl group in
MUA. After chip preparation and polymer placement, we modified DF6392 antibodies
specific to (CD44), prevalent on (MM) cell surfaces. The QCM chip underwent
immobilization of antibodies. Following this, the QCM chip coated with nanoparticles
and attached with antibodies underwent characterization using (AFM) (atomic force
microscopy), (FTIR-ATR) Spectroscopy )Fourier transform infrared-attenuated total
reflectance(, and contact angle measurements. After the characterization studies, the
functionalized QCM chip was exposed to A375 cell samples spanning from 50 to 5000
cells/mL at a flow rate of 1mL/min, and (f) (the resonance frequency) was then recorded,
to carry out kinetic, affinity studies and to determine the adsorption model. The Langmuir
isotherm model provides the best fit for the binding mode. To demonstrate the selectivity
of the modified QCM chip with DF6392 antibodies, (HEK293) human embryonic kidney
293 cell line, and (PANC-1) human pancreatic cancer cell line, were absorbed onto the
QCM chip in competition, at a rate of 2500 cells/mL. Real-time detection was employed
to monitor the mass changes (∆m) on the sensor's surface, measured in cell/cm2 units.
(LOD)(the system's detection limit) stood at 1.2 cells/mL. The QCM biosensor exhibited
23.34 times greater selectivity for A375 cells compared to PANC-1 cells and 9.24 times
more selective than HEK293 cells. This receptor antibody-functionalized system shows
promise for effectively detecting MM cells. These findings indicate that the QCM
biosensor is a highly selective, efficient, and sensitive system suitable for cancer cell
detection.