High-aspect-ratio microdevices and methods for transdermal delivery and sampling of active substances

US 7,591,806 B2
Filed: 05/18/2005
Issued: 09/22/2009
Est. Priority Date: 05/18/2004
Status: Active Grant

First Claim

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1. A method of making a microfabricated device for delivery of an active agent comprising:

performing a first isotropic etch to define microneedle tips, microblade edge, or microknife edge of the device,performing a second anisotropic Bosch etch to define microneedle shaft, microblade body, or microknife body of the device, thereby forming the device, andforming the device,wherein the microfabricated device comprises a structure formed of a material selected from the group consisting of metals, ceramics, silicon, glass, polymers, and combinations thereof,wherein the structure is selected from the group consisting of solid microneedles, solid microblades, solid microknives, and a combination thereof,wherein the microneedles, microblades, or microknives have and aspect ration of about 10;

1 or higher.

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Abstract

High-aspect-ratio microdevices comprising microneedles, microknives and microblades and their manufacturing methods are disclosed. These devices can be used for the delivery of therapeutic agents across the skin or other tissue barriers to allow chemical and biological molecules getting into the circulation systems. The microneedles can also be used to withdraw body fluids for analysis of clinically relevant species when the device has an integrated body fluid sensor or sensor array in the vicinity of microneedles.

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6 Claims

1. A method of making a microfabricated device for delivery of an active agent comprising:
- performing a first isotropic etch to define microneedle tips, microblade edge, or microknife edge of the device,performing a second anisotropic Bosch etch to define microneedle shaft, microblade body, or microknife body of the device, thereby forming the device, andforming the device,wherein the microfabricated device comprises a structure formed of a material selected from the group consisting of metals, ceramics, silicon, glass, polymers, and combinations thereof,wherein the structure is selected from the group consisting of solid microneedles, solid microblades, solid microknives, and a combination thereof,wherein the microneedles, microblades, or microknives have and aspect ration of about 10;
  
  1 or higher.

2. A method of making a microfabricated device for delivery of an active agent comprising:
- performing an anisotropic etch first to define the body of microneedle, microblade or microknife device,and performing orientation dependent etch of Si using potassium hydroxide or tetramethyl ammonium hydroxide or sodium hydroxide solution, thereby forming the device,wherein the microfabricated device comprises a structure formed of a material selected from the group consisting of metals, ceramics, silicon, glass, polymers, and combinations thereof,wherein the structure is selected from the group consisting of solid microneedles, solid microblades, solid microknives, and a combination thereof,wherein the microneedles, microblades, or microknives have and aspect ration of about 10;
  
  1 or higher.

3. A method of making a microfabricated device for delivery of an active agent comprisingmoving one or two electrodes comprising a working electrode which is a cathode and a counter electrode which is an anode during an electrochemical etch to define the body of the microneedle, microblade, or microknife of the device, andforming the device,wherein the microfabricated device comprises a structure formed of a material selected from the group consisting of metals, ceramics, silicon, glass, polymers, and combinations thereof,wherein the structure is selected from the group consisting of solid microneedles, solid microblades, solid microknives, and a combination thereof,wherein the microneedles, microblades, or microknives have and aspect ration of about 10:
- 1 or higher.

4. A microfabricated device for delivery of an active agent produced by a process comprising:
- performing a first isotropic etch to define microneedle tips, microblade edge, or microknife edge,performing a second anisotropic Bosch etch to define microneedle shaft, microblade body, or microknife body, thereby forming the device, andforming the microfabricated device,wherein the microfabricated device comprises a structure formed of a material selected from the group consisting of metals, ceramics, silicon, glass, polymers, and combinations thereof,wherein the structure is selected from the group consisting of solid microneedles, solid microblades, solid microknives, and a combination thereof,wherein the microneedles, microblades, or microknives have and aspect ration of about 10;
  
  1 or higher.

5. A microfabricated device for delivery of an active agent produced by a process comprising:
- performing an anisotropic etch first to define the body of a microneedle, microblade, or microknife, and performing orientation dependent etch of Si using potassium hydroxide or tetramethyl ammonium hydroxide or sodium hydroxide solution, thereby forming the microfabricated device,wherein the microfabricated device comprises a structure formed of a material selected from the group consisting of metals, ceramics, silicon, glass, polymers, and combinations thereof,wherein the structure is selected from the group consisting of solid microneedles, solid microblades, solid microknives, and a combination thereof,wherein the microneedles, microblades, or microknives have and aspect ration of about 10;
  
  1 or higher.

6. A microfabricated device for delivery of an active agent produced by a process comprising:
- moving one or two electrodes comprising a working electrode which is a cathode and a counter electrode which is a patterned anode during electrochemical etch, and forming the microfabricated device,wherein the microfabricated device comprises a structure formed of a material selected from the group consisting of metals, ceramics, silicon, glass, polymers, and combinations thereof,wherein the structure is selected from the group consisting of solid microneedles, solid microblades, solid microknives, and a combination thereof,wherein the microneedles, microblades, or microknives have and aspect ration of about 10;
  
  1 or higher.

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Current Assignee
Bai Xu
Original Assignee
Bai Xu
Inventors
Xu, Bai
Primary Examiner(s)
Lucchesi; Nicholas D
Assistant Examiner(s)
Bouchelle; Laura A

Application Number

US10/908,584
Publication Number

US 20050261632A1
Time in Patent Office

1,588 Days
Field of Search

604/171, 604/272, 604/219, 424/451, 606/185, 216/41, 438/706
US Class Current

604/272
CPC Class Codes

A61K 9/0021   Intradermal administration,...

A61M 2037/0046   Solid microneedles

A61M 2037/0053   Methods for producing micro...

A61M 37/0015   by using microneedles

B82Y 10/00   Nanotechnology for informat...

B82Y 5/00   Nanobiotechnology or nanome...

Y02A 50/30   Against vector-borne diseas...

High-aspect-ratio microdevices and methods for transdermal delivery and sampling of active substances

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High-aspect-ratio microdevices and methods for transdermal delivery and sampling of active substances

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