An apparatus for injectate delivery includes a cartridge, a linear actuator, a rotary motor mechanically coupled the actuator, and a controller coupled to the motor. The controller controls a linear motion of the actuator by controlling an electrical input supplied to the motor in a first interval during which the motor is stationary with the linear actuator engaged with the cartridge to displace an injectate in the cartridge, a second interval following the first interval during which the controller accelerates the motor from stationary to a first speed selected to create a jet of the injectate from the cartridge with a velocity sufficient to pierce human tissue to a subcutaneous depth, a third interval during which the controller maintains the motor at or above the first speed, and a fourth interval during which the controller decelerates the motor to a second speed to deliver the injectate at the subcutaneous depth.

An apparatus for use in injectate delivery includes an actuator including a linkage, a force generating mechanism mechanically coupled to the linkage, and a controller coupled to the force generating mechanism. The force generating mechanism includes a passive force generator and an active force generator. In operation and on the basis of a control signal, the controller is configured to control the force generating mechanism to provide an input force to the linkage that is a combination of the first force provided by the passive force generator and a second force provided by the active force generator.

The invention proposes a method and a device for needleless injection of liquid into a substrate, in particular of a liquid pharmaceutical or cosmetic preparation into a biological tissue, making it possible in a particularly advantageous manner to reliably inject a liquid completely into the substrate without a needle. In accordance with the invention, this is achieved by a sequential injection, wherein a first partial quantity of the liquid first exits from an outlet nozzle at a very high outlet velocity as a fine liquid jet under high pressure generated in the liquid by means of a impulse shock and enters the substrate and creates an injection channel in the substrate, into which a second partial quantity of the liquid is then introduced at lower pressure and lower velocity. Preferably, the ejected liquid jet is set in rotation around its jet axis before it impinges on the substrate, so that the jet receives a helical movement and thus practically drills into the substrate without splashing away laterally.

A needleless injector includes a cap, an injection system, a body, a gas generator, and a percussion device. The body is covered by the cap and is mounted to slide relative to the cap. The percussion device includes a striker that is slidingly mounted along a sliding axis between a rest position and a percussion position and a lock mechanism. The lock mechanism includes a lug and a retention tab. The lug projects from a peripheral face of the striker along an axis that is perpendicular to the sliding axis and has a first support ramp. The retention tab is attached to the cap, and has a second support ramp. The ramps are configured to move the retention tab radially when pushed by the striker from a retaining position to a release position and the retention tab is moved aside to release the striker.

A therapeutic agent injection device including an injection device for delivering a therapeutic agent to a patient having a body, the body having a patient face and a port face opposite the patient face, the port face having an introducer port including an introducer channel and an injection port including an injection channel, the introducer channel being in fluid communication with the injection channel through a cross channel, the injection channel defining an injection axis; a delivery tube for subcutaneous delivery of the therapeutic agent to the patient, the delivery tube projecting from and being generally perpendicular to the patient face, the delivery tube defining an introducer axis and being in fluid communication with the injection port; and a patch, the patch being attached to the patient face and being operable to adhesively attach to the patient; wherein the injection axis is parallel to the introducer axis.

The invention proposes a method and a device for needleless injection of liquid into a substrate, in particular of a liquid pharmaceutical or cosmetic preparation into a biological tissue, which makes it possible in a particularly advantageous manner to reliably inject a particularly fine liquid jet into the substrate without a significant increase in the static pressure in the liquid during the injection process. According to the invention, this is achieved by first accelerating the liquid received in a liquid container together with the latter to an initial velocity before the movement of the liquid container is stopped again, while simultaneously ejecting the liquid from the liquid container through an outlet nozzle under at least partial retention of its movement. Preferably, the ejected liquid jet is set in rotation about its jet axis before it impinges on the substrate, so that the jet receives a helical movement and thus practically drills into the substrate without splashing away laterally.

This invention provides an insulin injection device, comprising: a wearable module, a detection module and a drug administration module, wherein the wearable module is used for fixing the detection module and the drug administration module to a body of a user; the detection module is used for detecting a blood glucose concentration of the user, determining a dose of required insulin according to the blood glucose concentration, generating a corresponding drug administration instruction according to the dose of the required insulin, and sending the drug administration instruction to the drug administration module; and the drug administration module is used for storing the insulin and injecting a corresponding dose of insulin into the body of the user according to the drug administration instruction. The device can bring convenience to patients regarding usage.

Provided are a device whereby, during process of a process target such as a cell or the like, localized process of a process part is possible without inflicting damage due to heat, and rejoining and regeneration may proceed readily subsequent to process, and whereby an injection substance may be introduced efficiently; and a device for generating bubbles containing a plasma.

Through the use of a localized ablation device employing a bubble jetting member having a core formed from a conductive material, a shell part formed from an insulating material, covering the core and including a section extending from the tip of the core, and a space formed between the extended section of the shell part and the tip of the core, a process target can be treated in localized fashion and without inflicting damage. By further providing an outside shell part at the outer periphery of the shell part, bubbles onto which a solution containing an injection substance has been adsorbed can be ejected, and the injection substance can be introduced during localized ablation of the process target. Additionally, by including a pair of electrodes formed from a conducting material, for generating a plasma in an inert gas, a liquid flow passage through which a liquid flows, and a microscopic flow passage for flow of an inert gas, an inert gas containing a plasma, and bubbles of inert gas containing a plasma, the liquid flow passage and the microscopic flow passage connecting at the downstream side from a section in which plasma is generated in the microscopic flow passage, bubbles containing a plasma can be generated, and can maintain a plasma state even in liquid, whereby therapy of biological tissue can be effected with the plasma.

The present Invention relates to a kit for applying a liquid composition on or in the skin, comprising an injection device and one or more cartridges, provided with a container appropriate for receiving a liquid composition, in which the injection device is provided with means for receiving a cartridges, characterized in that the container is provided with a movable body. The cartridge is provided with a peripheral edge, that allows the safe removal of a used cartridge out of the device, In a second aspect, the invention relates to a method for applying a liquid composition onto the skin.

A needleless syringe comprises a main syringe body which is a main body thereof and which has, in the main body, a sliding movement passage connected to an opening provided on a front end surface of the main body; a holding unit which has an accommodating unit for accommodating an injection objective substance so that the injection objective substance is releasable; and a driver that is configured to apply energy to the holding unit in order to allow the holding unit to slide toward the opening. When the energy is applied by the driver to the holding unit disposed at the initial position, the holding unit slides in the sliding movement passage to abut against the opening at the abutment position, and thus the injection objective substance accommodated in the accommodating unit is discharged via the opening. Accordingly, the high injection performance of the needleless syringe is appropriately exhibited.