Method and apparatus for enhancement of transdermal transport

Abstract

According to the present invention, a method for enhancing transdermal transport is disclosed. The method includes the steps of increasing a permeability of an area of a membrane with a permeabilizing device. The membrane may be, inter alia, biologic skin or synthetic skin. The permeabilizing device may be an ultrasound-producing device. A substance is transported into and through the area of the membrane. The substance may be a drug, a vaccine, or a component of interstitial fluid.

Description

[0001] 1. Field of the Invention[0002] This invention relates to transdermal molecular transportation. More specifically, this invention relates to methods and apparatus for the regulation of skin permeabilization and analysis of analytes in extracted body fluid.[0003] 2. Description of the Related Art[0004] Drugs are routinely administered either orally or by injection. The effectiveness of most drugs relies on achieving a certain concentration in the bloodstream. Although some drugs have inherent side effects which cannot be eliminated in any dosage form, many drugs exhibit undesirable behaviors that are specifically related to a particular route of administration. For example, drugs may be degraded in the GI tract by the low gastric pH, local enzymes or interaction with food or drink within the stomach. The drug or disease itself may forestall or compromise drug absorption because of vomiting or diarrhea. If a drug entity survives its trip through the GI tract, it may face rapid ...

AI Technical Summary

Benefits of technology

[0044] In another embodiment of the present invention, ultrasound is used to irritate or inflame an area of skin. Next, a vaccine is provided to the irritated or inflamed skin. This is more effective in inducing the immune response of the body.

Problems solved by technology

Although some drugs have inherent side effects which cannot be eliminated in any dosage form, many drugs exhibit undesirable behaviors that are specifically related to a particular route of administration.

The drug or disease itself may forestall or compromise drug absorption because of vomiting or diarrhea.

Sometimes the drug itself has inherent undesirable attributes such as a short half-life or a narrow therapeutic blood level range.

The transport of drugs to, into, out of, and through the skin is complex since many factors influence their permeation.

In spite of these advantages, very few drugs and no proteins or peptides are currently administered transdermally for clinical applications because of the low skin permeability to drugs.

Use of these gels may be messy and labor-intensive.

This method of glucose measurement has the major disadvantage that it is painful, so diabetics do not like to obtain a glucose measurement as often as is medically indicated.

A problem with methods that penetrate the skin to obtain interstitial fluid is that interstitial fluid occurs in the body in a gel like form with little free fluid and, in fact, is even under negative pressure that limits the amount of free interstitial fluid that can be obtained.

Large forces can be produced locally, resulting in cavitation, mechanical oscillations in the skin itself, and large localized shearing forces near the surface of the skin.

Ultrasound transducers are known to rapidly heat under continuous operation, reaching temperatures that can cause skin damage.

In the case of analyte extraction, compounds present on the surface of and / or in the skin can contaminate the extracted sample.

The level of contamination increases as skin surface area increases.

Moreover, as discussed above, overexposure to ultrasound and cavitation can cause damage to the skin through heating and increased pressure.

That is, application of ultrasound having a particular frequency will disorganize the lipid bilayer in the skin and thus increase the permeability of the skin.

That is, overexposure to ultrasound may cause skin damage from increased heat, increased pressure and other factors.

At higher frequencies, however, the capacitive component to the impedance of the parallel combination decreases and, therefore, the overall impedance of the "skin circuit" declines.

The current source may also be similarly limited.

When ultrasound is used, the permeability enhancement obtained by supplying ultrasound is limited.

That is, once a certain permeability is reached, the further application of ultrasound will not further enhance skin permeability.

Overexposure to ultrasound, or cavitation caused thereby, may result in damage to the skin from localized pressure, temperature increases, and shear stresses.

This is done so that the predetermined value is not "overshot," thereby increasing the risk of skin damage.

The current source may also be suitably limited.

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