Your search keyword '"Langenbacher RE"' showing total 5 results

1. Hematoxylin Nuclear Stain Reports Oxidative Stress via Near-Infrared Emission.

Author

Langenbacher RE, Horoszko CP, Kim M, and Heller DA

Subjects

Humans, Eosine Yellowish-(YS), Ferric Compounds, Ferritins, Hematoxylin, Iron, Coloring Agents, Oxidative Stress physiology

Abstract

Hematoxylin & eosin (H&E) is the gold standard histological stain used for medical diagnosis and has been used for over a century. Herein, we examined the near-infrared II (NIR-II) fluorescence of this stain. We observed significant NIR-II emission from the hematoxylin component of the H&E stain. We found that the emission intensity, using the common aluminum(III) hematoxylin mordant, could be modulated by the availability of endogenous iron(III), and this emission intensity increased at higher oxidative stress. Our mechanistic investigations found that hematoxylin emission reported the nuclear translocation of the iron via the protein ferritin. In human tumor tissue samples, oxidative stress biomarkers correlated with hematoxylin NIR-II emission intensity. Emission response of the stain was also observed in human Alzheimer's disease brain tissue regions affected by disease progression, suggesting that ferritin nuclear translocation is preserved in these regions as an oxidative stress response. These findings indicate that NIR-II emission from the H&E stain provides a new source of redox information in tissues with implications for biomedical research and clinical practice.

Published

2023

2. Harnessing nanotechnology to expand the toolbox of chemical biology.

Author

Williams RM, Chen S, Langenbacher RE, Galassi TV, Harvey JD, Jena PV, Budhathoki-Uprety J, Luo M, and Heller DA

Subjects

Animals, Biocompatible Materials, Drug Carriers chemistry, Drug Delivery Systems, Enzymes chemistry, Humans, Molecular Biology methods, Molecular Imaging methods, Nanoparticles, Molecular Biology trends, Nanotechnology trends

Abstract

Although nanotechnology often addresses biomedical needs, nanoscale tools can also facilitate broad biological discovery. Nanoscale delivery, imaging, biosensing, and bioreactor technologies may address unmet questions at the interface between chemistry and biology. Currently, many chemical biologists do not include nanomaterials in their toolbox, and few investigators develop nanomaterials in the context of chemical tools to answer biological questions. We reason that the two fields are ripe with opportunity for greater synergy. Nanotechnologies can expand the utility of chemical tools in the hands of chemical biologists, for example, through controlled delivery of reactive and/or toxic compounds or signal-binding events of small molecules in living systems. Conversely, chemical biologists can work with nanotechnologists to address challenging biological questions that are inaccessible to both communities. This Perspective aims to introduce the chemical biology community to nanotechnologies that may expand their methodologies while inspiring nanotechnologists to address questions relevant to chemical biology.

Published

2021

3. Polymer cloaking modulates the carbon nanotube protein corona and delivery into cancer cells.

Author

Budhathoki-Uprety J, Harvey JD, Isaac E, Williams RM, Galassi TV, Langenbacher RE, and Heller DA

Abstract

Carbon nanotube-based molecular probes, imaging agents, and biosensors in cells and in vivo continue to garner interest as investigational tools and clinical devices due to their unique photophysical properties. Surface chemistry modulation of nanotubes plays a critical role in determining stability and interaction with biological systems both in vitro and in vivo. Among the many parameters that influence the biological fate of nanomaterials, surface charge is particularly influential due to direct electrostatic interactions with components of the cell membrane as well as proteins in the serum, which coat the nanoparticle surface in a protein corona and alter nanoparticle-cell interactions. Here, we modulated functional moieties on a helical polycarbodiimide polymer backbone that non-covalently suspended the nanotubes in aqueous media. By derivatizing the polymer with either primary amine or carboxylic acid side chains, we obtained nanotube complexes that present net surface charges of opposite polarity at physiological pH. Using these materials, we found that the uptake of carbon nanotubes in these cells is highly dependent on charge, with cationic nanotubes efficiently internalized into cells compared to the anionic nanotubes. Furthermore, we found that serum proteins drastically influenced cell uptake of the anionic nanotubes, while the effect was not prominent for the cationic nanotubes. Our findings have implications for improved engineering of drug delivery devices, molecular probes, and biosensors.

Published

2017

4. A Carbon Nanotube Optical Sensor Reports Nuclear Entry via a Noncanonical Pathway.

Author

Budhathoki-Uprety J, Langenbacher RE, Jena PV, Roxbury D, and Heller DA

Subjects

Active Transport, Cell Nucleus, HeLa Cells, Humans, Luminescent Agents chemistry, Microscopy, Fluorescence, Molecular Structure, Nanotubes, Carbon chemistry, Polymers chemistry, Tumor Cells, Cultured, Cell Nucleus metabolism, Luminescent Agents metabolism, Nanotubes, Carbon analysis, Optical Imaging

Abstract

Single-walled carbon nanotubes are of interest in biomedicine for imaging and molecular sensing applications and as shuttles for various cargos such as chemotherapeutic drugs, peptides, proteins, and oligonucleotides. Carbon nanotube surface chemistry can be modulated for subcellular targeting while preserving photoluminescence for label-free visualization in complex biological environments, making them attractive materials for such studies. The cell nucleus is a potential target for many pathologies including cancer and infectious diseases. Understanding mechanisms of nanomaterial delivery to the nucleus may facilitate diagnostics, drug development, and gene-editing tools. Currently, there are no systematic studies to understand how these nanomaterials gain access to the nucleus. Herein, we developed a carbon nanotube based hybrid material that elucidate a distinct mechanism of nuclear translocation of a nanomaterial in cultured cells. We developed a nuclear-targeted probe via cloaking photoluminescent single-walled carbon nanotubes in a guanidinium-functionalized helical polycarbodiimide. We found that the nuclear entry of the nanotubes was mediated by the import receptor importin β without the aid of importin α and not by the more common importin α/β pathway. Additionally, the nanotube photoluminescence exhibited distinct red-shifting upon entry to the nucleus, potentially functioning as a reporter of the importin β-mediated nuclear transport process. This work delineates a noncanonical mechanism for nanomaterial delivery to the nucleus and provides a reporter for the study of nucleus-related pathologies.

Published

2017

5. Measurement of heterogeneous reaction rates: three strategies for controlling mass transport and their application to indium-mediated allylations.

Author

Olson IA, Bacon WA, Baez Sosa YY, Delaney KM, Forte SA, Guglielmo MA, Hill AN, Kiesow KH, Langenbacher RE, Xun Y, Young RO, and Bowyer WJ

Subjects

Allyl Compounds chemistry, Hydrocarbons, Halogenated chemistry, Molecular Structure, Organometallic Compounds chemical synthesis, Particle Size, Photomicrography, Solutions, Stereoisomerism, Surface Properties, Allyl Compounds chemical synthesis, Indium chemistry, Organometallic Compounds chemistry

Abstract

We describe three new strategies for determining heterogeneous reaction rates using photomicroscopy to measure the rate of retreat of metal surfaces: (i) spheres in a stirred solution, (ii) microscopic powder in an unstirred solution, and (iii) spheres on a rotating shaft. The strategies are applied to indium-mediated allylation (IMA), which is a powerful tool for synthetic chemists because of its stereoselectivity, broad applicability, and high yields. The rate-limiting step of IMA, reaction of allyl halides at indium metal surfaces, is shown to be fast, with a minimum value of the heterogeneous rate constant of 1 × 10(-2) cm/s, an order of magnitude faster than the previously determined minimum value. The strategies described here can be applied to any reaction in which the surface is retreating or advancing, thereby broadening the applicability of photomicroscopy to measuring heterogeneous reaction kinetics.

Published

2011