1 Introduction
2 Nanoneedles
2.1 Fabrication of Nanoneedles
2.1.1 Bottom-Up Strategy
Methods | Fabrication illustrations | SEM images | Materials | Advantages | Typical limitations | Typical applications |
---|---|---|---|---|---|---|
Bottom-up | ||||||
Chemical vapor deposition | Solid nanoneedles | Silicon, Carbon, GaN | High efficiency, high repeatability | Expensive equipment, high production cost | Cell sensing, cell drug delivery | |
Atom layer deposition | Hollow nanoneedles | Ni Al2O3 | High machining accuracy, high aspect ratio, fit for hollow nanoneedle | Expensive equipment, multiple steps, low efficiency | Gene delivery, protein extraction | |
Top-down | ||||||
Metal-assisted chemical etch | Porous nanoneedles | Silicon | High efficiency, simple process, low cost, fit for mass production | Random distribution, wide dimension | Cell drug delivery, cell sensing | |
Reactive ion etch | Hollow nanoneedles | Silicon SiO2/Si | High machining accuracy, highly ordered, better controllability | Expensive equipment, high resolution mask, low flexible | Cell drug delivery | |
Focused ion beam | Hollow nanoneedles | Silicon | Good flexibility, high aspect ratio, fine controllability, fit for hollow nanoneedle | Expensive equipment, low efficiency | Cell drug delivery, cell sensing | |
Nanoimprinting | Solid nanoneedles | Aluminum | High resolution, low cost, high consistency, fit for mass production | Multiple steps, low flexible, high precision mold | Biosensing |
2.1.2 Top-Down Approach
2.2 Intracellular Applications of Nanoneedles
2.2.1 Cell Sensing
Sensing methods | Schematic illustration | SEM images | Performance |
---|---|---|---|
Electrical signals | |||
Electrochemilu-minescence |
2.2.2 Cell Drug Delivery
Nanoneedles | Schematic illustration | SEM images | Delivery performance |
---|---|---|---|
Solid nanoneedle | |||
Hollow nanoneedle |
3 Microneedles
3.1 Fabrication of Microneedles
3.1.1 Subtractive Manufacturing
Fabrication methods | Fabrication illustrations | SEM images | Materials | Advantages | Typical limitations | Typical applications |
---|---|---|---|---|---|---|
Photolithography and etching | Solid microneedles | Silicon, Tungsten | High precision, high efficiency, fit for mass production | Expensive equipment, harsh environment, multiple steps | Bio-sensoring, drug delivery | |
Micro machining | ||||||
Laser machining | Solid microneedles | Copper, Titanium, Stainless steel | High efficiency, maskless, high flexibility, non-contact machining | Rough surface quality, lower machining accuracy, arced needle tip | Bio-electrode, bio-sensoring, drug delivery, bioinspired microneedles | |
Mililing machining | Solid microneedles | Aluminum alloy, Stainless steel 316L | High precision, good surface quality | Low efficiency, high cost | Microneedle template | |
Wire electrical discharge machining | Solid microneedles | Stainless steel | High precision, good aspect ratio, reproducibility | Time consuming, limited material | Bio-electrode |
3.1.2 Formative Manufacturing
Methods | Fabrication illustrations | SEM images | Materials | Advantages | Typical limitations | Typical applications |
---|---|---|---|---|---|---|
Micro casting | Solid microneedles | Polymer, Hydrogel | High efficiency, low cost, easy operation, fit for mass production | High resolution mold, low flexibility, multiple steps | Bio-electrode, transdermal drug delivery, triboelectric nanogenerator | |
Micro injection molding | Porous microneedles | Titanium, Stainless steel 316L, Aluminum | Fit for porous microneedle, controllable porosity | Low efficiency, low flexible, multiple steps | Transdermal drug delivery, bio-sensing |
3.1.3 Additive Manufacturing
Methods | Fabrication illustrations | SEM images | Materials | Advantages | Typical limitations | Typical applications |
---|---|---|---|---|---|---|
Typical 3D printing | ||||||
Stereolithography |
〹 | Solid microneedles | Photo curable polymer | High efficiency, high repeatability, high flexibility | Poor surface quality, rough surface, large tip radius | Transdermal drug delivery |
Digital light processing | Bioinspired microneedles | Photo curable polymer | Complex 3D structure, high flexibility, non-contact machining | Rough surface, limited materials, | Transdermal drug delivery, fog harvest | |
Drawing method | ||||||
Thermal drawing | Solid microneedles | SU-8, PLGA, Maltose | High aspect ratio, high efficiency, maskless | Low repeatability, limited materials, high temperature | Bio-electrode, brain-computer interface | |
Magnetorheological drawing | Bioinspired microneedles | Curable magnetorheological fluid | One-step fabrication, maskless, high flexibility | Low biocompatibility, limited material | Transdermal drug delivery, bio-electrode, bio-sensing |
3.2 Biomedical Applications of Microneedles
3.2.1 Transdermal Biosensing
Strategies | Microneedle images | Schematic illustration | Test results |
---|---|---|---|
Sampling | |||
Interstitial fluid | |||
Blood | |||
Detecting | |||
Electrochemistry | |||
Photochemical sensor |
3.2.2 Transdermal Drug Delivery
Delivery strategies | Device images | Schematic illustration | Delivery performance |
---|---|---|---|
Passive release | |||
Active release | |||
Responsive release |
4 Millineedles
4.1 Fabrication of Millineedles
4.2 Applications of Millineedles
Millineedles types | Millineedles images | Applications images |
---|---|---|
Puncture | ||
Syringe | ||
Acupuncture | ||
Suture |