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Deposition of Tin Oxide Nanoparticles for Electrochemical Studies of Amyloid Peptides
ALEJANDRA M. DE JESUS SOTOKENNY J. COLON COLONRISE PROGRAM
Concepts:• Nanoparticles
• Microscopic material that has physical dimensions ranging between 1-100 nmOtaño-Rivera W. 2014. Introducción a los Conceptos de la Nanotecnología y su Importancia Científica
• Amyloid Peptides:• Molecular markers
• Diagnosis and prognosis of Alzheimer’s disease
• Transcription factor
• Anti-microbial activity
• Kinase enzyme activator
http://nanogloss.com/wp-content/uploads/2009/08/white-light-nanoparticles.jpg
Lin Liu. 2013. Electrochemical detection of β-amyloid peptides on electrode covered with N-terminus-specific antibody based on electrocatalytic O2 reduction by Aβ(1-16)-heme-modified gold nanoparticles
Why use nanoparticles?
• Higher surface area
• Higher sensitivity
• Low power consumption
• Development of better materials, devices and systems
• Applications in biomedical, optical and electronic fields
http://www.nap.edu/books/0309084547/xhtml/images/p2000a445g6001.jpg
Lin Liu. 2013. Electrochemical detection of β-amyloid peptides on electrode covered with N-terminus-specific antibody based on electrocatalytic O2 reduction by A β(1-16)-
heme-modified gold nanoparticles
Related studies • Backgrounder on Nanoparticles and Amyloid Diseases (Kulinowski, Unknown year of publication).• Reviewed studies regarding amyloid peptides in ex-
vivo experimentations
• Blood and cerebral spinal fluid testing outside the body
• Nanoparticles bind to biomolecules to produce signals
• Inhibition or reduction of Amyloid protein fibril production with nanoparticles
http://icon.rice.edu/resources.cfm?doc_id=10866
• Electrochemical detection of β-amyloid peptides on electrode covered with N-terminus-specific antibody based on electrocatalytic O2 reduction by Aβ(1-16)-heme-modified gold nanoparticles (Liu, et al. 2013).• Aβ(1-16)-heme-AuNPs detected Aβ testing it with cyclic
voltammetry.
• About 10 pM of Aβ was the detection limit of the Aβ(1-16)-heme-AuNPs .
• Its results are comparable with the Surface Plasmon Resonance (incidence of light on electrons of the substrate).
• Problem:•Does the sputtering procedure helps to spread a film of Tin oxide nanoparticles over a Silicium substrate and a Carbon glass substrate?
•Hypothesis• The sputtering procedure will deposit the Tin nanoparticles forming a film over an exposed area of the Silicium substrate and on the Carbon glass substrate.
Objectives:• Demonstrate that the
sputtering technique is an alternative for the development of thin film formations.
• Compare the final products in Silicium and Carbon glass substrates for differences.
• Help improve the affinity of Tin Oxide towards Amyloid Peptides by studying sputtering.
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Procedure
Prepare vacuum
chamber
Magnetron Sputtering SEM image
Procedure(Magnetron Sputtering)
Substrate(Anode)
Target(Cathode)
Argon Plasma(Ar+, Ar, e-, hυ)
Ar Ion
Sputtered particle
4. Electrons released during Argon ionization are accelerated to the substrate, subsequently colliding with additional Argon atoms, creating more ions and free electrons in the process, continuing the cycle.
1. Electrically neutral Argon atoms are introduced into a vacuum chamber.
2. DC (direct current) voltage is placed between the target and substrate which ionizes Argon atoms and creates a plasma (glow discharge)
3. These Argon ions accelerate to the target. Their collision with the target ejects target atoms, which travel to the substrate and eventually settle.Ionized Argon bombards a target, releasing atoms which form layers on a substrate.
http://www.pfonline.com/articles/vacuum-deposition-processes
• Physical process • In a vacuum
chamber, gas pressure is less than the ambient atmospheric pressure.
First Result• Si substrate
• 1 min.
• 50 W
• 160 ºC
• Bigger spheres due to high temperature and long period of exposure
Second Result• SiOx substrate
• 20 s
• 50 W
• Room temperature (21-23ºC)
• Uneven nanoparticles because of low temperature.
Third Result• Carbon glass
substrate
• 10 s
• 50 W
• 150 ºC
• Circular shaped nanoparticles because of balanced adjustments of temperature and time exposure
Results in Comparison
• Si substrate
• 1 min.
• 50 W
• 160 ºC
• SiOx substrate
• 20 s
• 50 W
• Room temperature (21-23ºC)
• Carbon glass substrate
• 10 s
• 50 W
• 150 ºC
Conclusions
• The sputtering system is a versatile technique for depositing any solid material• This procedure assures the deposition of
Tin nanoparticles film over the exposed area of the Silicium substrate.
• Although the tested carbon glass substrate did not result as figured, it was understood that the error was due to maladjustments on temperature and time exposure.
Future Research • Repeat the sputtering process on another glass Carbon substrate using another adjustments on temperature and exposure time.
• After obtaining a potential pure substrate product with the Tin oxide nanoparticle layer:• The product would be sent to Dr. Ana Guadalupes’ group
at UPR-Río Piedras for the testing part using Amyloid peptides.
• The electrochemical properties of the Amyloid peptides are studied doing cyclic voltammetry in relation to the Tin oxide nanoparticles and a Ferrocene connector.
ReferencesLiu L, Zhao F, Ma F, Zhang F, Yang S, Xia N. 2013.
Electrochemical detection of β-amyloid peptides on electrode covered with N-terminus-specific antibodybasedonelectrocatalyticO2 reduction by Aβ(1–16)-heme-modified gold nanoparticles. Biosensors and Bioelectronics; 49(2013): 231-235.
Otaño-Rivera W. 2014. Introducción a los Conceptos de la Nanotecnología y su Importancia Científica
Kulinowski. Unknown year of publication. Backgrounder on Nanoparticles and Amyloid Diseases
Acknowledgments
• Dr. Wilfredo Otaño
• Mr. José Cruz
• RISE Program at UPR Cayey
• UPR Cayey
Tin Oxide Nanoparticles for Electrochemical Studies of Amyloid Peptides
ALEJANDRA M. DE JESUS SOTOKENNY J. COLON COLONRISE PROGRAM
