TY  - JOUR
A1  - Oertel, Jana
A1  - Keller, Adrian
A1  - Prinz, Julia
A1  - Schreiber, Benjamin
A1  - Huebner, Rene
A1  - Kerbusch, Jochen
A1  - Bald, Ilko
A1  - Fahmy, Karim
T1  - Anisotropic metal growth on phospholipid nanodiscs via lipid bilayer expansion
JF  - Scientific reports
N2  - Self-assembling biomolecules provide attractive templates for the preparation of metallic nanostructures. However, the intuitive transfer of the "outer shape" of the assembled macromolecules to the final metallic particle depends on the intermolecular forces among the biomolecules which compete with interactions between template molecules and the metal during metallization. The shape of the bio-template may thus be more dynamic than generally assumed. Here, we have studied the metallization of phospholipid nanodiscs which are discoidal particles of similar to 10 nm diameter containing a lipid bilayer similar to 5 nm thick. Using negatively charged lipids, electrostatic adsorption of amine-coated Au nanoparticles was achieved and followed by electroless gold deposition. Whereas Au nanoparticle adsorption preserves the shape of the bio-template, metallization proceeds via invasion of Au into the hydrophobic core of the nanodisc. Thereby, the lipidic phase induces a lateral growth that increases the diameter but not the original thickness of the template. Infrared spectroscopy reveals lipid expansion and suggests the existence of internal gaps in the metallized nanodiscs, which is confirmed by surface-enhanced Raman scattering from the encapsulated lipids. Interference of metallic growth with non-covalent interactions can thus become itself a shape-determining factor in the metallization of particularly soft and structurally anisotropic biomaterials.
Y1  - 2016
U6  - https://doi.org/10.1038/srep26718
SN  - 2045-2322
VL  - 6
PB  - Nature Publ. Group
CY  - London
ER  - 
TY  - JOUR
A1  - Prinz, Julia
A1  - Heck, Christian
A1  - Ellerik, Lisa
A1  - Merk, Virginia
A1  - Bald, Ilko
T1  - DNA origami based Au-Ag-core-shell nanoparticle dimers with single-molecule SERS sensitivity
JF  - Nanoscale
N2  - DNA origami nanostructures are a versatile tool to arrange metal nanostructures and other chemical entities with nanometer precision. In this way gold nanoparticle dimers with defined distance can be constructed, which can be exploited as novel substrates for surface enhanced Raman scattering (SERS). We have optimized the size, composition and arrangement of Au/Ag nanoparticles to create intense SERS hot spots, with Raman enhancement up to 10(10), which is sufficient to detect single molecules by Raman scattering. This is demonstrated using single dye molecules (TAMRA and Cy3) placed into the center of the nanoparticle dimers. In conjunction with the DNA origami nanostructures novel SERS substrates are created, which can in the future be applied to the SERS analysis of more complex biomolecular targets, whose position and conformation within the SERS hot spot can be precisely controlled.
Y1  - 2016
U6  - https://doi.org/10.1039/c5nr08674d
SN  - 2040-3364
SN  - 2040-3372
VL  - 8
SP  - 5612
EP  - 5620
PB  - Royal Society of Chemistry
CY  - Cambridge
ER  - 
TY  - GEN
A1  - Prinz, Julia
A1  - Heck, Christian
A1  - Ellerik, Lisa
A1  - Merk, Virginia
A1  - Bald, Ilko
T1  - DNA origami based Au–Ag-core–shell nanoparticle dimers with single-molecule SERS sensitivity
N2  - DNA origami nanostructures are a versatile tool to arrange metal nanostructures and other chemical entities with nanometer precision. In this way gold nanoparticle dimers with defined distance can be constructed, which can be exploited as novel substrates for surface enhanced Raman scattering (SERS). We have optimized the size, composition and arrangement of Au/Ag nanoparticles to create intense SERS hot spots, with Raman enhancement up to 1010, which is sufficient to detect single molecules by Raman scattering. This is demonstrated using single dye molecules (TAMRA and Cy3) placed into the center of the nanoparticle dimers. In conjunction with the DNA origami nanostructures novel SERS substrates are created, which can in the future be applied to the SERS analysis of more complex biomolecular targets, whose position and conformation within the SERS hot spot can be precisely controlled.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 221 
Y1  - 2016
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-89714
SP  - 5612
EP  - 5620
ER  - 
TY  - JOUR
A1  - Prinz, Julia
A1  - Heck, Christian
A1  - Ellerik, Lisa
A1  - Merk, Virginia
A1  - Bald, Ilko
T1  - DNA origami based Au–Ag-core–shell nanoparticle dimers with single-molecule SERS sensitivity
JF  - Nanoscale
N2  - DNA origami nanostructures are a versatile tool to arrange metal nanostructures and other chemical entities with nanometer precision. In this way gold nanoparticle dimers with defined distance can be constructed, which can be exploited as novel substrates for surface enhanced Raman scattering (SERS). We have optimized the size, composition and arrangement of Au/Ag nanoparticles to create intense SERS hot spots, with Raman enhancement up to 1010, which is sufficient to detect single molecules by Raman scattering. This is demonstrated using single dye molecules (TAMRA and Cy3) placed into the center of the nanoparticle dimers. In conjunction with the DNA origami nanostructures novel SERS substrates are created, which can in the future be applied to the SERS analysis of more complex biomolecular targets, whose position and conformation within the SERS hot spot can be precisely controlled.
Y1  - 2016
U6  - https://doi.org/10.1039/C5NR08674D
IS  - 8
SP  - 5612
EP  - 5620
PB  - RSC Publishing
CY  - Cambridge
ER  - 
TY  - THES
A1  - Prinz, Julia
T1  - DNA origami substrates as a versatile tool for surface-enhanced Raman scattering (SERS)
T1  - DNA Origami-Substrate als ein vielseitiges Werkzeug für die oberflächenverstärkte Raman-Streuung (SERS)
N2  - Surface-enhanced Raman scattering (SERS) is a promising tool to obtain rich chemical information about analytes at trace levels. However, in order to perform selective experiments on individual molecules, two fundamental requirements have to be fulfilled. On the one hand, areas with high local field enhancement, so-called “hot spots”, have to be created by positioning the supporting metal surfaces in close proximity to each other. In most cases hot spots are formed in the gap between adjacent metal nanoparticles (NPs). On the other hand, the analyte has to be positioned directly in the hot spot in order to profit from the highest signal amplification. The use of DNA origami substrates provides both, the arrangement of AuNPs with nm precision as well as the ability to bind analyte molecules at predefined positions. Consequently, the present cumulative doctoral thesis aims at the development of a novel SERS substrate based on a DNA origami template. To this end, two DNA-functionalized gold nanoparticles (AuNPs) are attached to one DNA origami substrate resulting in the formation of a AuNP dimer and thus in a hot spot within the corresponding gap. The obtained structures are characterized by correlated atomic force microscopy (AFM) and SERS imaging which allows for the combination of structural and chemical information.
Initially, the proof-of principle is presented which demonstrates the potential of the novel approach. It is shown that the Raman signal of 15 nm AuNPs coated with dye-modified DNA
(dye: carboxytetramethylrhodamine (TAMRA)) is significantly higher for AuNP dimers arranged on a DNA origami platform in comparison to single AuNPs. Furthermore, by attaching single TAMRA molecules in the hot spot between two 5 nm AuNPs and optimizing the size of the AuNPs by electroless gold deposition, SERS experiments at the few-molecule level are presented. The initially used DNA origami-AuNPs design is further optimized in many respects. On the one hand, larger AuNPs up to a diameter of 60 nm are used which are additionally treated with a silver enhancement solution to obtain Au-Ag-core-shell NPs. On the other hand, the arrangement of both AuNPs is altered to improve the position of the dye molecule within the hot spot as well as to decrease the gap size between the two particles. With the optimized design the detection of single dye molecules (TAMRA and cyanine 3 (Cy3)) by means of SERS is demonstrated. Quantitatively, enhancement factors up to 10^10 are estimated which is sufficiently high to detect single dye molecules.
In the second part, the influence of graphene as an additional component of the SERS substrate is investigated. Graphene is a two-dimensional material with an outstanding combination of electronical, mechanical and optical properties. Here, it is demonstrated that
single layer graphene (SLG) replicates the shape of underlying non-modified DNA origami
substrates very well, which enables the monitoring of structural alterations by AFM imaging.
In this way, it is shown that graphene encapsulation significantly increases the structural
stability of bare DNA origami substrates towards mechanical force and prolonged exposure
to deionized water.
Furthermore, SLG is used to cover DNA origami substrates which are functionalized with a
40 nm AuNP dimer. In this way, a novel kind of hybrid material is created which exhibits
several advantages compared to the analogue non-covered SERS substrates. First, the fluorescence background of dye molecules that are located in between the AuNP surface and SLG is efficiently reduced. Second, the photobleaching rate of the incorporated dye molecules is decreased up to one order of magnitude. Third, due to the increased photostability of the investigated dye molecules, the performance of polarization-dependent series measurements on individual structures is enabled. This in turn reveals extensive information about the dye molecules in the hot spot as well as about the strain induced within the graphene lattice.
Although SLG can significantly influence the SERS substrate in the aforementioned ways, all
those effects are strongly related to the extent of contact with the underlying AuNP dimer.
N2  - Desoxyribonukleinsäure (engl. deoxyribonucleic acid (DNA)) ist nicht nur Träger der Erbinformation, sondern wird auch seit den frühen 80er Jahren als Gerüstmaterial in der Nanotechnologie verwendet. Im Jahr 2006 wurde die bis dato entwickelte DNA-Nanotechnologie durch die Erfindung der sogenannten DNA Origami-Technik weiter revolutioniert. Diese erlaubt die Konstruktion vielfältiger zwei- und dreidimensionaler Strukturen durch gezielte DNA-Selbstassemblierung. Basierend auf der grundlegenden Watson-Crick Basenpaarung innerhalb eines DNA-Doppelstrangs können die gewünschten Zielstrukturen dabei mit hoher Genauigkeit vorhergesagt werden.
Neben der Entwicklung vielfältiger DNA-Konstrukte eignen sich DNA Origami-Substrate zudem hervorragend zur Bindung funktionaler Einheiten mit der Präzision im Bereich von
Nanometern. Somit lassen sich beispielsweise Goldnanopartikel (AuNPs) präzise anordnen.
Dies ist von höchstem Interesse im Zusammenhang mit der oberflächenverstärkten
Ramanstreuung (engl. surface-enhanced Raman scattering (SERS)). SERS basiert darauf,
die naturgemäß schwache Ramanstreuung eines Analyten um mehrere Größenordnungen zu verstärken, indem der Analyt nahe einer Metalloberfläche positioniert wird. Die Verstärkung der Ramanstreuung beruht hierbei hauptsächlich auf der Wechselwirkung des Analyten mit dem elektromagnetischen Feld der Metalloberfläche und kann im Zwischenraum zweier benachbarter Metallstrukturen besonders stark ausgeprägt sein.
Die vorliegende kumulative Dissertation beschäftigt sich mit der Entwicklung einer DNA
Origami-basierten Sensoroberfläche für die Anwendung von SERS-Experimenten. Hierbei
werden jeweils zwei AuNPs in gezieltem Abstand an ein DNA Origami-Substrat gebunden und
das verstärkte Ramansignal eines Analyten im Zwischenraum des AuNP-Dimers detektiert.
Zunächst wird das allgemeine Prinzip in Form eines Wirksamkeitsnachweises vorgestellt, in
welchem der Farbstoff Carboxytetramethylrhodamin (TAMRA) als Analyt verwendet wird.
Die darauf aufbauenden Experimente zielen auf eine Verringerung der Nachweisgrenze bis
hin zur Einzelmoleküldetektion ab. Im Zuge dessen werden vielseitige Optimierungsschritte
durchgeführt, die die Größe, die Anordnung sowie die Ummantelung der AuNPs mit einer
dünnen Silberschicht betreffen. Es wird gezeigt, dass durch die Optimierung aller Parameter
die Detektion einzelner TAMRA- und Cyanin 3 (Cy3)-Moleküle mittels SERS möglich ist.
Weiterhin wird Graphen, ein erst im Jahr 2004 entdecktes Material bestehend aus einer
einzigen Schicht Kohlenstoffatome, als weiterer Bestandteil der untersuchten Nanostrukturen
eingeführt. Graphen zeichnet sich durch eine bislang einzigartige Kombination aus optischen, elektronischen und mechanischen Eigenschaften aus und hat sich daher innerhalb kürzester Zeit zu einem vielfältigen Forschungsschwerpunkt entwickelt. In der vorliegenden Dissertation wird zunächst die erhöhte strukturelle Stabilität von Graphen bedeckten DNA Origami-Substraten im Hinblick auf mechanische Beanspruchung sowie auf die Inkubation in deionisiertem Wasser demonstriert. In weiterführenden Betrachtungen werden auch DNA Origami-Substrate, die mit AuNP-Dimeren funktionalisiert sind, mit Graphen bedeckt, und somit eine neuartige Hybridstruktur erzeugt. Es wird gezeigt, dass Graphen den Fluoreszenzuntergrund der untersuchten Farbstoffmoleküle deutlich reduziert und zusätzlich deren Photostabilität gegenüber der eintreffenden Laserstrahlung effektiv verbessert.
KW  - DNA origami
KW  - surface-enhanced Raman scattering
KW  - DNA nanostructures
KW  - graphene
KW  - single-molecule detection
KW  - DNA Origami
KW  - oberflächenverstärkte Raman-Streuung
KW  - DNA Nanostrukturen
KW  - Graphen
KW  - Einzelmoleküldetektion
Y1  - 2016
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-104089
ER  - 
TY  - JOUR
A1  - Matkovic, Aleksandar
A1  - Vasic, Borislav
A1  - Pesic, Jelena
A1  - Prinz, Julia
A1  - Bald, Ilko
A1  - Milosavljevic, Aleksandar R.
A1  - Gajic, Rados
T1  - Enhanced structural stability of DNA origami nanostructures by graphene encapsulation
JF  - NEW JOURNAL OF PHYSICS
N2  - We demonstrate that a single-layer graphene replicates the shape of DNA origami nanostructures very well. It can be employed as a protective layer for the enhancement of structural stability of DNA origami nanostructures. Using the AFM based manipulation, we show that the normal force required to damage graphene encapsulated DNA origami nanostructures is over an order of magnitude greater than for the unprotected ones. In addition, we show that graphene encapsulation offers protection to the DNA origami nanostructures against prolonged exposure to deionized water, and multiple immersions. Through these results we demonstrate that graphene encapsulated DNA origami nanostructures are strong enough to sustain various solution phase processing, lithography and transfer steps, thus extending the limits of DNA-mediated bottom-up fabrication.
KW  - graphene
KW  - DNA origami nanostructures
KW  - atomic force microscopy
Y1  - 2016
U6  - https://doi.org/10.1088/1367-2630/18/2/025016
SN  - 1367-2630
VL  - 18
PB  - IOP Publ. Ltd.
CY  - Bristol
ER  - 
TY  - JOUR
A1  - Prinz, Julia
A1  - Matkovic, Aleksandar
A1  - Pesic, Jelena
A1  - Gajic, Rados
A1  - Bald, Ilko
T1  - Hybrid Structures for Surface-Enhanced Raman Scattering: DNA Origami/Gold Nanoparticle Dimer/Graphene
JF  - Small
N2  - A combination of three innovative materials within one hybrid structure to explore the synergistic interaction of their individual properties is presented. The unique electronic, mechanical, and thermal properties of graphene are combined with the plasmonic properties of gold nanoparticle (AuNP) dimers, which are assembled using DNA origami nanostructures. This novel hybrid structure is characterized by means of correlated atomic force microscopy and surface-enhanced Raman scattering (SERS). It is demonstrated that strong interactions between graphene and AuNPs result in superior SERS performance of the hybrid structure compared to their individual components. This is particularly evident in efficient fluorescence quenching, reduced background, and a decrease of the photobleaching rate up to one order of magnitude. The versatility of DNA origami structures to serve as interface for complex and precise arrangements of nanoparticles and other functional entities provides the basis to further exploit the potential of the here presented DNA origami-AuNP dimer-graphene hybrid structures.
Y1  - 2016
U6  - https://doi.org/10.1002/smll.201601908
SN  - 1613-6810
SN  - 1613-6829
VL  - 12
SP  - 5458
EP  - 5467
PB  - Wiley-VCH
CY  - Weinheim
ER  -