A method for manufacturing a fine hollow protruding article (1) according to the invention involves: a protrusion forming step of bringing a projecting mold part (11) that includes a heating means into contact from one surface (2D) side of a base sheet (2) including a thermoplastic resin, and, while softening, with heat, a contact section (TP) in the base sheet (2) where the projecting mold part (11) contacts the base sheet (2), inserting the projecting mold part (11) into the base sheet (2), to form a protrusion (3) that protrudes from the other surface (2U) side of the base sheet (2); a cooling step of cooling the protrusion (3) in a state where the projecting mold part (11) is inserted in an interior of the protrusion (3); and a release step of withdrawing the projecting mold part (11) from the interior of the protrusion (3) after the cooling step, to form the fine hollow protruding article (1).

Methods, structures, and systems are disclosed for biosensing and drug delivery techniques. In one aspect, a^ device for detecting an analyte and/or releasing a biochemical into a biological fluid can include an array of hollowed needles, in which each needle includes a protruded needle structure including an exterior wall forming a hollow interior and an opening at a terminal end of the protruded needle structure that exposes the hollow interior, and a probe inside the exterior wall to interact with one or more chemical or biological substances that come in contact with the probe via the opening to produce a probe sensing signal, and an array of wires that are coupled to probes of the array of hollowed needles, respectively, each wire being electrically conductive to transmit the probe sensing signal produced by a respective probe.

A preparation delivery assembly includes: a first substrate, a second substrate, and at least two needles of different lengths. Two side walls are provided between the first and second substrates to define a first chamber. At least one first channel that is in communication with the first chamber is provided in the second substrate in a direction perpendicular to the second substrate. And the needles are arranged on a surface of the second substrate, and each needle is in communication with the first chamber to deliver the preparation. A third channel is provided in the first substrate in a direction perpendicular to the first substrate, and one end of the third channel is in communication with the first chamber so as to guide the preparation introduced from the other end of the third channel into the first chamber.

The present invention relates to a micro-needle (7; 8; 9) for the transdermal administration of active molecules and/or for the sampling of biological fluids. The micro-needle (7; 8; 9) is made of polymeric material through photolithography. A cavity is defined in the micro-needle (7; 8; 9).

The present invention further relates to a method for obtaining through photolithography at least one micro-needle (7; 8; 9) for the transdermal administration of active molecules and/or for the sampling of biological fluids. A photo-cross linking polymer is exposed in liquid phase to an energy radiation causing the hardening thereof. A photolithographic mask (1; 2) is interposed between the source of the energy radiation and the photo-cross linking polymer. The photolithographic mask (1; 2) is configured in a manner such to generate in the photo-cross linking polymer a peripheral shadow area, a central shadow area and a lighting area confined between the peripheral shadow area and the central shadow area.

The method according to this invention is aimed at obtaining a micro-needle (7; 8; 9) for the transdermal administration of active molecules and/or for the sampling of biological fluids which shows the peculiar characteristic of being hollow and which is manufactured by means of a single photolithography operation, thus avoiding the use of additional processing.

A core-shell microneedle system and a method of manufacturing the microneedle system provides a pulsatile drug delivery system which is programmed to release drugs/vaccines at predictable times using biodegradable polymers and with controllable dosages. This microneedle system can be fully embedded into the skin and then release drugs/vaccines as sharp bursts in a timely manner, similar to multiple bolus injections.

A fluid delivery system including a first balloon and a second balloon at least partially positioned within the first balloon, wherein the second balloon has an inner surface, an outer surface, and at least one micro-needle extending outwardly from the outer surface of the second balloon. The delivery system can further include a fluid source in communication with at least one of the micro-needles of the second balloon.

A microneedle having a body including a base, shaft and pointed tip, and at least one lumen disposed within the shaft. The lumen having an opening that is offset from the tip and open to the exterior of the microneedle.

Provided herein are devices and methods for topically and controllably delivering cargo across or into biological tissues, particularly the skin. These devices permit delivery of cargo to deeper cell layers of a tissue. These devices include microstructure arrays comprising nanochannels. Also disclosed is a device comprising a one or more microstructure arrays encased in a frame.

A device that may be placed on a biological barrier can be used to perforate the biological barrier for a variety of purposes such as cosmetic, scar treatment or for the delivery of active agents. A flexible substrate has a first side and a second opposing side and a plurality of micro-penetrator arrangements each comprising a head and a first and second projection, for penetrating a biological barrier, extending from the head. The first and second projection at least partially extend through the flexible substrate towards the first side. The head comprises an elongate arm for spacing apart the first and second projections. A force is applied to the second side causing flexing of the flexible substrate and pushing the projections into communication with a biological barrier.

A device for delivering a fluid into a biological tissue includes hollow microneedles (10) projecting from a surface (12) of a substrate (14), and a guide element (18) spaced from the substrate. The guide element provides a tissue-contact surface (20) that defines a tissue contact plane oblique to the surface (12) of the substrate (14).