FITC-dextrans in neurobiological research

Hultström, Dieter.

January 1982

Thesis (doctoral)--Uppsala University, 1982. / Includes bibliographical references (p. 35-39).

Models for the Transfer of Drugs from the Nasal Cavity to the Central Nervous System

Jansson, Björn

January 2004

<p>The blood-brain barrier restricts the access of many compounds, including therapeutic agents, to the brain. Several human studies indicate that nasal administration of hydrophilic compounds, such as peptides, can bypass the blood-brain barrier. The aims of this thesis were to develop and refine models for this direct nose-to-brain transfer.</p><p>In a mouse model, [³H]-dopamine was given as a unilateral nasal dose. The resulting radioactivity in the ipsilateral olfactory bulb was significantly higher than that in the contralateral bulb and peaked at 4 h. Tape section autoradiography showed that the radioactivity was concentrated in the olfactory nerve layer and the glomerular layer of the olfactory bulb. The olfactory transfer of dopamine was also studied <i>in vitro</i>. At a lower donor concentration, the mucosal-to-serosal dopamine permeability was higher than the serosal-to-mucosal permeability, but at a higher concentration, the permeability coefficients were similar. Together, these results suggest that the olfactory transfer of dopamine has an active component.</p><p>Olfactory transfer of fluorescein-labeled dextran through the epithelium and deeper tissues was studied in a rat model, which enabled visualization of the transfer using fluorescence microscopy. Although the epithelial transfer appeared to be mainly intracellular, transfer in the following deeper tissues was extracellular. Without altering the route of uptake, a gellan gum formulation enhanced the uptake of fluorescein dextran. The enhancing effect was considered likely to be the result of an increased residence time in the nasal cavity.</p><p>In conclusion, dopamine and fluorescein-labeled dextran were identified as suitable model compounds for the study of olfactory drug transfer mechanisms and the influence of drug formulation. Two new <i>in vitro</i> models of olfactory transfer were compared. Also, a rat model, which enabled the visualization of the entire nose-to-brain transfer, was developed.</p>

Biopharmacy

Administration

intranasal

Nasal mucosa

Central nervous system

Olfactory bulb

Rat

Mouse

Swine

Cattle

Diffusion chambers

culture

In vitro

Biological models

Biological transport

Dextrans

Dopamine

Gels

Polysaccharides

Autoradiography

Fluorescence microscopy

Biofarmaci

Biopharmacy

Biofarmaci

Models for the Transfer of Drugs from the Nasal Cavity to the Central Nervous System

Jansson, Björn

January 2004

The blood-brain barrier restricts the access of many compounds, including therapeutic agents, to the brain. Several human studies indicate that nasal administration of hydrophilic compounds, such as peptides, can bypass the blood-brain barrier. The aims of this thesis were to develop and refine models for this direct nose-to-brain transfer. In a mouse model, [3H]-dopamine was given as a unilateral nasal dose. The resulting radioactivity in the ipsilateral olfactory bulb was significantly higher than that in the contralateral bulb and peaked at 4 h. Tape section autoradiography showed that the radioactivity was concentrated in the olfactory nerve layer and the glomerular layer of the olfactory bulb. The olfactory transfer of dopamine was also studied in vitro. At a lower donor concentration, the mucosal-to-serosal dopamine permeability was higher than the serosal-to-mucosal permeability, but at a higher concentration, the permeability coefficients were similar. Together, these results suggest that the olfactory transfer of dopamine has an active component. Olfactory transfer of fluorescein-labeled dextran through the epithelium and deeper tissues was studied in a rat model, which enabled visualization of the transfer using fluorescence microscopy. Although the epithelial transfer appeared to be mainly intracellular, transfer in the following deeper tissues was extracellular. Without altering the route of uptake, a gellan gum formulation enhanced the uptake of fluorescein dextran. The enhancing effect was considered likely to be the result of an increased residence time in the nasal cavity. In conclusion, dopamine and fluorescein-labeled dextran were identified as suitable model compounds for the study of olfactory drug transfer mechanisms and the influence of drug formulation. Two new in vitro models of olfactory transfer were compared. Also, a rat model, which enabled the visualization of the entire nose-to-brain transfer, was developed.

Biopharmacy

Administration

intranasal

Nasal mucosa

Central nervous system

Olfactory bulb

Rat

Mouse

Swine

Cattle

Diffusion chambers

culture

In vitro

Biological models

Biological transport

Dextrans

Dopamine

Gels

Polysaccharides

Autoradiography

Fluorescence microscopy

Biofarmaci

Biopharmacy

Biofarmaci

Photoacoustic drug delivery using carbon nanoparticles activated by femtosecond and nanosecond laser pulses

Chakravarty, Prerona

09 January 2009

Cellular internalization of large therapeutic agents such as proteins or nucleic acids is a challenging task because of the presence of the plasma membrane. One strategy to facilitate intracellular drug uptake is to induce transient pores in the cell membrane through physical delivery strategies. Physical approaches are attractive as they offer more generic applicability compared with viral or biochemical counterparts. Pulsed laser light can induce the endothermic carbon-steam reaction in carbon-nanoparticle suspensions to produce explosive photoacoustic effects in the surrounding medium. In this study, for the first time, these photoacoustic forces were used to transiently permeabilize the cell membrane to deliver macromolecules into cells. Intracellular delivery using this method was demonstrated in multiple cell types for uptake of small molecules, proteins and DNA. At optimized conditions, uptake was seen in up to 50% of cells with nearly 100% viability and in 90% of cells with ≥90% viability, which compared favorably with other physical methods of drug delivery. Cellular bioeffects were shown to be a consequence of laser-carbon interaction and correlated with properties of the carbon and laser, such as carbon concentration and size, laser pulse duration, wavelength, intensity and exposure time. Similar results were observed using two different lasers, a femtosecond Ti: Sapphire laser and a nanosecond Nd: YAG laser. Uptake was also shown in murine skeletal muscles in vivo with up to 40% efficiency compared to non-irradiated controls. This synergistic use of nanotechnology with advanced laser technology could provide an alternative to viral and chemical-based drug and gene delivery.

Ultrashort laser pulses

Multiwalled carbon nanotubes

Luciferase

GFP

Dextrans

BSA

Calcein

Gold nanorods

Intracellular delivery

Physical method

Whisker mediated transformation

Silicon carbide

Tissue culture

Ultrasound

Loblolly pine

Acoustooptical devices

Drug delivery systems

Femtosecond lasers

Nanotechnology

Lasers in medicine