阅读说明：本技术 制备三维图案化的多材料水凝胶异质结构的装置及方法 (Device and method for preparing three-dimensional patterned multi-material hydrogel heterostructure ) 是由 弥胜利 黄哲鑫 黄玉 于 2021-07-07 设计创作，主要内容包括：一种用于制备三维图案化的多材料水凝胶异质结构的装置及方法,该装置包括注射泵、工作液池、打印针嘴及三轴平移装置,注射泵作为液体双向驱动和计量装置,打印针嘴安装于三轴平移装置上,实现打印针嘴的移动和定位,工作液池包括原液池和打印液池,原液池中设置有多个储液槽,分别存放不同材料的水凝胶预配液。本发明以水凝胶微球作为构建单元的方式实现多材料图案化水凝胶结构的制备,采用“液滴序列生成-液滴打印”的打印策略,对于水凝胶材料组分的种类数量具有良好的通用性,制备的多材料水凝胶异质结构具有较高的图案化分辨率,可制备较复杂的三维结构,如可用于水凝胶致动结构和类器官等的制备。(The device comprises an injection pump, a working solution pool, a printing needle nozzle and a three-axis translation device, wherein the injection pump is used as a liquid bidirectional driving and metering device, the printing needle nozzle is installed on the three-axis translation device to realize the movement and the positioning of the printing needle nozzle, the working solution pool comprises a stock solution pool and a printing solution pool, a plurality of liquid storage tanks are arranged in the stock solution pool, and hydrogel pre-prepared liquid of different materials is respectively stored in the liquid storage tanks. The invention realizes the preparation of the multi-material patterned hydrogel structure by taking hydrogel microspheres as construction units, adopts a printing strategy of 'droplet sequence generation-droplet printing', has good universality on the number of types of hydrogel material components, and the prepared multi-material hydrogel heterostructure has higher patterning resolution, can prepare more complex three-dimensional structures, and can be used for preparing hydrogel actuating structures, similar organs and the like.)

1. A device for preparing a three-dimensional patterned multi-material hydrogel heterostructure is characterized by comprising an injection pump, a working liquid pool, a printing needle nozzle and a three-axis translation device, wherein the injection pump is connected with the printing needle nozzle through a conduit and is used as a liquid bidirectional driving and metering device, the printing needle nozzle is installed on the three-axis translation device, the three-axis translation device realizes the movement and the positioning of the printing needle nozzle, the working liquid pool comprises a stock solution pool and a printing liquid pool, the stock solution pool is of a double-layer structure, a plurality of liquid storage tanks are arranged on the lower layer, hydrogel pre-prepared liquids of different materials are respectively stored in different liquid storage tanks, the liquid storage tanks are covered by oil phase liquid containing amphiphilic molecules on the upper layer of the stock solution pool, and the oil phase liquid containing the amphiphilic molecules is stored in the printing liquid pool in advance; when a droplet sequence is generated, the three-axis translation device positions the printing needle nozzle into aqueous phase liquid in different liquid storage tanks and oil phase liquid on the upper layer of the stock solution tank, the injection pump performs liquid suction with a preset volume and alternately sucks the oil phase liquid and different aqueous phase liquid to generate a water-in-oil droplet sequence containing different material components, wherein amphiphilic molecules in the oil phase are distributed on a water-oil interface through diffusion to form a single-layer amphiphilic molecule membrane; in the process of droplet printing, the three-axis translation device positions the printing needle nozzle to a preset position in oil-phase liquid in the printing liquid pool, the injection pump extrudes corresponding droplets to the preset position in the oil-phase liquid, and spatial arrangement of the droplets is realized, wherein one droplet is contacted with at least one other adjacent droplet, a bilayer of amphiphilic molecules is formed at the contact position, droplet connection and liquid encapsulation are realized, and a three-dimensional patterned droplet stack structure is formed.

2. The apparatus for preparing a three-dimensionally patterned multi-material hydrogel heterostructure of claim 1, further comprising a uv light curing device for curing and crosslinking the droplet stack structure by uv light to form a microgel network.

3. The apparatus for preparing a three-dimensionally patterned multi-material hydrogel heterostructure according to claim 1 or 2, further comprising a calibration platform on which the working fluid bath is disposed, the calibration platform for adjusting and calibrating a horizontal position and an angular position of the working fluid bath relative to the printing needle nozzle before droplet printing, measuring an origin position, and setting a printing coordinate system.

4. The apparatus according to any of claims 1 to 3, wherein the working fluid reservoir further comprises a cleaning fluid reservoir containing a cleaning fluid, and the triaxial translation apparatus further positions the printing tip end into the cleaning fluid reservoir for washing prior to drawing a different fluid.

5. The apparatus for preparing a three-dimensionally patterned multi-material hydrogel heterostructure according to any one of claims 1 to 4, wherein the tip of the printing tip is formed in a tapered shape, and the outer and inner walls of the tip are hydrophobized.

6. The apparatus for preparing a three-dimensionally patterned multi-material hydrogel heterostructure according to any one of claims 1 to 5, wherein at least one reservoir in the stock solution tank stores therein separately a non-gellable aqueous liquid in advance as a stock solution for supporting the liquid droplets, for being sucked to generate the structural liquid droplets containing the gellable hydrogel prepad liquid and the supporting liquid droplets containing the non-gellable aqueous liquid, and the preparation of the hollow and suspended structure is realized by using the liquid droplets containing the non-gellable liquid as a support.

7. The apparatus for producing three-dimensionally patterned multi-material hydrogel heterostructures according to any of claims 1 to 6, wherein the printing fluid bath achieves anchoring of the printed droplets by means of an array of grooves or surface wettability treatment.

8. The apparatus for fabricating three-dimensionally patterned multi-material hydrogel heterostructures according to any one of claims 1 to 7, wherein the material of the working fluid bath is selected from any one of glass, Polydimethylsiloxane (PDMS), Polymethylmethacrylate (PMMA).

9. The apparatus for preparing a three-dimensionally patterned multi-material hydrogel heterostructure according to any of claims 1 to 8, wherein the amphiphilic molecules in the oil phase are selected from phospholipid molecules, preferably from phosphatidylcholine (phosphotidylline), 1, 2-diphytane-sn-glycero-3-phosphocholine (DPhPC), 1, 2-dioleoylphosphate-sn-glycero-3-phosphocholine (DOPC), 1, 2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC), and the oil phase solvent used is selected from hexadecane, silicone oil AR20, and mixtures thereof.

10. A method for producing a three-dimensionally patterned multi-material hydrogel heterostructure, characterized in that the production of the three-dimensionally patterned multi-material hydrogel heterostructure is carried out using the apparatus for producing a three-dimensionally patterned multi-material hydrogel heterostructure according to any of claims 1 to 9.

Technical Field

The invention relates to the field of multi-material hydrogel structure preparation, in particular to a device and a method for preparing a three-dimensional patterned multi-material hydrogel heterostructure.

Background

Hydrogel is a biomaterial consisting of a three-dimensional network structure composed of hydrophilic polymer chains and an aqueous solution therein, which is considered as a potential biomaterial due to its high water content and good biocompatibility, and is widely used for research in the field of bio-manufacturing, and is valued by many scientific researchers. Various new types of hydrogels have been developed for use in the field of biological tissue engineering, such as hydrogel scaffolds/dressings for tissue repair and reconstruction. Secondly, hydrogel materials are also widely used as biological research carriers, such as cell culture matrices and organoid models, and drug delivery carriers, such as hydrogel microparticles/microcapsules. In addition, since various stimulus-responsive materials have been developed and synthesized and hydrogels have been made multifunctional, hydrogel machines, including hydrogel actuators, sensors, optical and electronic components, etc., have also been extensively studied.

Tissues and organs in living organisms are composed of a large number of repeating functional units and are characterized by heterogeneity and hierarchical structure. The ultimate goal of bio-fabrication is to mimic in vivo tissue, so it is desirable for hydrogel-based bio-fabrication to mimic the heterogeneous characteristics and microstructure of in vivo tissue by combining multiple different hydrogel materials, i.e., by multi-material hydrogel heterostructures. This is referred to herein as "patterning of the hydrogel heterostructure".

Two examples in different fields of application are listed here. The first example is the application of in vitro culture systems, such as artificial biological scaffolds and dressings constructed in vitro or in vivo in situ for repairing diseased and damaged tissues or for promoting tissue regeneration to achieve tissue function improvement or reconstruction, and organoids used for research in disease pathology, regeneration mechanism, precision medicine, and drug screening, which require the simulated construction of the internal microstructure or microenvironment of the biological tissue.

A second example is the application in hydrogel machines, for example by combining different stimuli-responsive materials, which under different stimulus conditions have different swelling responses, resulting in an inhomogeneous distribution of the stress on the hydrogel structure, resulting in an actuation action, which is the principle of hydrogel actuation structures based on multi-material combinations.

At present, there are many preparation methods for hydrogel heterostructure, including preparation method of hydrogel fiber and hydrogel microsphere based on microfluidics, 3d printing method of hydrogel based on extrusion or inkjet, preparation method of hydrogel multilayer structure based on photolithography, etc. These methods all suffer from drawbacks such as poor expandability of microfluidic-based hydrogel fiber and hydrogel microsphere preparation methods, inability to prepare complex shapes; the extrusion type or ink jet type hydrogel 3d printing method is limited by printing ink materials, a nozzle can be blocked when the gel speed is too high, the shape fidelity is poor when the gel speed is too low, the gel speed and the printing performance of the hydrogel need to be regulated and controlled in the printing process, the nozzle can be blocked when the gel speed is too high, the formability and the shape fidelity are poor when the gel speed is too low, and the material selection for the biological ink is few. The preparation method of the hydrogel multilayer structure based on photoetching is more suitable for interlayer distribution of materials, and is mostly only used for preparing structures with larger sizes; and so on.

It is to be noted that the information disclosed in the above background section is only for understanding the background of the present application and thus may include information that does not constitute prior art known to a person of ordinary skill in the art.

Disclosure of Invention

The main objective of the present invention is to overcome the above-mentioned drawbacks of the background art, and to provide an apparatus and method for preparing a three-dimensionally patterned multi-material hydrogel heterostructure.

In order to achieve the purpose, the invention adopts the following technical scheme:

an apparatus for preparing a three-dimensional patterned multi-material hydrogel heterostructure comprises an injection pump, a working solution pool, a printing needle nozzle and a three-axis translation device, the injection pump is connected with the printing needle nozzle through a conduit and is used as a liquid bidirectional driving and metering device, the printing needle nozzle is arranged on the three-axis translation device, the three-axis translation device realizes the movement and the positioning of the printing needle nozzle, the working liquid pool comprises a stock solution pool and a printing liquid pool, a plurality of liquid storage tanks are arranged in the stock solution pool and respectively store hydrogel pre-prepared liquid of different materials, the stock solution tank is of a double-layer structure, a plurality of liquid storage tanks are arranged on the lower layer, hydrogel pre-prepared liquid of different materials is respectively stored in different liquid storage tanks, covering the liquid storage tank with oil phase liquid containing amphiphilic molecules on the upper layer of the stock solution tank, and storing the oil phase liquid containing the amphiphilic molecules in the printing solution tank in advance; when a droplet sequence is generated, the three-axis translation device positions the printing needle nozzle into aqueous phase liquid in different liquid storage tanks and oil phase liquid on the upper layer of the stock solution tank, the injection pump performs liquid suction with a preset volume and alternately sucks the oil phase liquid and different aqueous phase liquid to generate a water-in-oil droplet sequence containing different material components, wherein amphiphilic molecules in the oil phase are distributed on a water-oil interface through diffusion to form a single-layer amphiphilic molecule membrane; in the process of droplet printing, the three-axis translation device positions the printing needle nozzle to a preset position in oil-phase liquid in the printing liquid pool, the injection pump extrudes corresponding droplets to the preset position in the oil-phase liquid, and spatial arrangement of the droplets is realized, wherein one droplet is contacted with at least one other adjacent droplet, a bilayer of amphiphilic molecules is formed at the contact position, droplet connection and liquid encapsulation are realized, and a three-dimensional patterned droplet stack structure is formed.

Further:

the device also comprises an ultraviolet light curing device which is used for curing and crosslinking the liquid drop stacking structure through ultraviolet light to form a microgel network.

The liquid drop printing device is characterized by further comprising a calibration platform, wherein the working liquid pool is arranged on the calibration platform, the calibration platform is used for adjusting and calibrating the horizontal position of the working liquid pool and the angle position relative to the printing needle nozzle before liquid drop printing, measuring the position of an original point and setting a printing coordinate system.

The working liquid pool further comprises a cleaning liquid tank in which cleaning liquid is stored, and before different liquids are sucked, the triaxial translation device further positions the tail end of the printing needle nozzle into the cleaning liquid tank for cleaning.

The tip of the printing needle nozzle is formed into a pointed cone shape, and the outer wall and the inner wall of the tip are hydrophobized by silanization treatment or by other hydrophobizing agent treatment.

The liquid drop is absorbed to generate a structural liquid drop containing the gelation hydrogel prepad liquid and a supporting liquid drop containing the gelation aqueous phase liquid, and the preparation of the hollow and suspended structure can be realized by taking the liquid drop containing the gelation-free liquid as the support.

The printing liquid pool realizes the anchoring of the printed liquid drop through a groove array or a surface wettability treatment mode.

The material of the working liquid pool is selected from any one of glass, Polydimethylsiloxane (PDMS) and polymethyl methacrylate (PMMA).

The amphiphilic molecules in the oil phase are selected from the group consisting of phospholipid molecules, preferably from phosphatidylcholine (phosphatydilcholine), 1, 2-diphytane-sn-glycero-3-phosphocholine (DPhPC), 1, 2-dioleoylphosphate-sn-glycero-3-phosphocholine (DOPC), 1, 2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC), the oil phase solvent used being selected from the group consisting of hexadecane, silicone oil AR20, and mixtures thereof.

A method for producing a three-dimensionally patterned multi-material hydrogel heterostructure, characterized in that the production of the three-dimensionally patterned multi-material hydrogel heterostructure is performed using the apparatus for producing a three-dimensionally patterned multi-material hydrogel heterostructure.

Compared with the prior art, the invention has the following beneficial effects:

the invention provides a device and a method for preparing a three-dimensional patterned multi-material hydrogel heterostructure, which realize the preparation of the multi-material patterned hydrogel structure through a microgel network, namely, a mode of taking hydrogel microspheres as construction units. Wherein the patterning and preparation of the microgel network is achieved by network printing of droplets. The drop network printing adopts a printing strategy of 'drop sequence generation-drop printing', adopts an 'active suction and extrusion' mode, and has the advantages of high flexibility, suitability for combination of any number of different materials, simple control and capability of realizing resolution of a single drop level. The invention has good universality for the number of types of hydrogel material components, and the prepared multi-material hydrogel heterostructure has higher patterning resolution, and can prepare more complex three-dimensional structures, such as hydrogel actuating structures, organs and the like.

According to the invention, the liquid drops with different volumes and material components can be generated in a liquid drop generation mode as required, the components and the material components of a single liquid drop and the distance between two liquid drops are directly and accurately controlled, the number of the types of the liquid drops is not limited, a plurality of liquid drop generators are not required, and the flexibility and the universality are high. The volume control of the liquid drop generation is only determined by the liquid metering and driving device, the control is simple, the influence of the liquid characteristics in the liquid drop is small, and the nano-scale liquid drop generation can be realized. In addition, the printing needle nozzle can sequentially suck different liquid phases with certain volumes in different stock solution pools continuously, so that the mixing operation of different liquid phases according to different proportions is realized, and mixed liquid drops are generated. For droplet sequencing, simultaneous droplet generation and sequencing can be achieved, no additional droplet screening and sequencing steps are required, and control at a single droplet level can be achieved.

The invention provides a novel preparation method of a hydrogel structure of multiple material components, namely droplet network printing-microgel network solidification, which takes droplets as basic components and can realize the preparation of the hydrogel of the multiple material components by assembling the droplets containing different material components, is not limited by the number of printing nozzles and has high flexibility and universality; in drop printing, patterning at single drop resolution can be achieved. The self-retaining property of the liquid drop network can be realized by utilizing a liquid drop interface double-layer film (DIB), and the modulation of the gel speed of the printing ink in the traditional hydrogel extrusion type printing and ink-jet printing processes can be avoided.

Drawings

Fig. 1 is a schematic structural diagram of an apparatus for preparing a three-dimensional patterned multi-material hydrogel heterostructure according to an embodiment of the present invention.

FIG. 2 is a schematic diagram of the preparation of a three-dimensional patterned multi-material hydrogel heterostructure using an apparatus of an embodiment of the present invention.

Detailed Description

The embodiments of the present invention will be described in detail below. It should be emphasized that the following description is merely exemplary in nature and is not intended to limit the scope of the invention or its application.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element. In addition, the connection may be for either a fixed or coupled or communicating function.

It is to be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in an orientation or positional relationship indicated in the drawings for convenience in describing the embodiments of the present invention and to simplify the description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed in a particular orientation, and be in any way limiting of the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the embodiments of the present invention, "a plurality" means two or more unless specifically limited otherwise.

The invention provides a three-dimensional microgel network assembled by hydrogel microspheres with various different material components by utilizing a droplet network in a mode of generation of a droplet sequence, printing of a patterned droplet network and solidification of the microgel network. Wherein, the droplet network (droplet network) refers to a droplet assembly formed by droplet encapsulation and connection through bimolecular layers (DIB) of amphiphilic molecules among droplets; the microgel network (microgel network) is a hydrogel structure assembled by taking hydrogel microparticles as construction units.

Referring to fig. 1 and 2, an apparatus for preparing a three-dimensionally patterned multi-material hydrogel heterostructure according to an embodiment of the present invention includes a syringe pump 1; a working fluid tank 2; a printing needle nozzle 3; a three-axis translation device 4. In other embodiments, other mating devices may be included, such as calibration platform 5, observation cameras, temperature measurement and control devices, air purification devices, and the like.

The syringe pump 1 has a function of programmable two modes of suction and extrusion, is connected with the printing needle nozzle 3 through a conduit, and is used as a liquid bidirectional driving and metering device. The printing needle nozzle 3 is mounted on a three-axis translation device 4. The three-axis translation device 4 realizes the movement and the positioning of the printing needle nozzle and is matched with the injection pump 1 for operation. The working solution pool 2 comprises a stock solution pool and a printing solution pool, wherein the stock solution pool is provided with a plurality of liquid storage tanks for storing different hydrogel pre-prepared solutions and other aqueous phase liquids, such as more than two hydrogel pre-prepared solutions, a cleaning solution (cleaning buffer solution), deionized water and the like. The stock solution pool and the printing solution pool of the working solution pool are both covered by oil phase containing amphiphilic molecules. The printing liquid pool is of a double-layer structure, a plurality of liquid storage tanks are arranged on the lower layer of the stock solution pool, hydrogel pre-prepared liquids made of different materials are stored in the different liquid storage tanks respectively, the liquid storage tanks are covered by oil-phase liquid containing amphiphilic molecules on the upper layer of the stock solution pool, and the oil-phase liquid containing the amphiphilic molecules is stored in the printing liquid pool in advance. In the step of generating the liquid drop sequence, the three-axis translation device 4 firstly positions the printing needle nozzle 3 to the water phase liquid of different liquid storage tanks in the stock solution pool of the working solution pool 2 and the oil phase liquid on the upper layer of the stock solution pool, the injection pump 1 performs liquid suction with a preset volume, generates water-in-oil liquid drops by alternately sucking the oil phase liquid and the different water phase liquids, and can generate the liquid drop sequence containing different material components as required by repeating the operation. For example, in a conduit, amphipathic molecules in the oil phase are distributed at the water-oil interface, i.e., the surface of the aqueous phase droplets, by diffusion to form a monolayer of amphipathic molecules film. In the process of droplet printing, the three-axis translation device 4 positions the printing needle nozzle 3 to a preset position in oil-phase liquid in a printing liquid pool of the working liquid pool 2, the injection pump 1 extrudes droplets, corresponding droplets are placed at the preset position in the oil-phase liquid, and the operation is repeated to realize spatial arrangement of the droplets. Wherein, one liquid drop is contacted with at least one other adjacent liquid drop, and a bilayer of amphiphilic molecules is formed at the contact position of the liquid drops, so that the liquid drop connection and the liquid encapsulation are realized. In this way, a three-dimensional, stacked assembly of droplets, i.e. a three-dimensionally patterned network of droplets, is formed. The calibration platform 5 adjusts and calibrates the horizontal position of the working solution pool and the angle position relative to the printing needle nozzle before droplet printing, measures the position of the origin, and sets a printing coordinate system. The finally formed micro-droplet network can be crosslinked through subsequent ultraviolet light curing to form a hydrogel structure. Wherein, the bimolecular layer of the amphiphilic molecules between the liquid drops is unstable and cracked in the cross-linking process, and the hydrogel microspheres are connected to form a microgel network.

The upper layer of the stock solution pool stores oil phase liquid, and the oil phase liquid of the upper layer covers the water phase liquid in the liquid storage tank of the lower layer, so that the oil phase stock solution is used as the oil phase stock solution when liquid drops are generated, and the oil phase stock solution also has the functions of oil sealing and preventing the water phase from evaporating. The printing liquid pool is pre-stored with oil phase liquid, the liquid drop is printed in the oil phase liquid during printing, the printed water phase liquid drop can be completely covered by oil phase, on one hand, the formed single layer film is protected, on the other hand, more amphiphilic molecules are provided to ensure the formation of double molecular layers, in addition, as the water phase liquid drop is small in size and large in surface area to volume ratio, evaporation is easy, the oil phase liquid also provides the functions of preventing evaporation and ensuring the volume precision of the liquid drop.

In a preferred embodiment, the stock solution of the support droplet is sucked to generate the structural droplet containing the gelable hydrogel prepad solution and the support droplet containing the non-gelable aqueous phase liquid, and the preparation of the hollow and suspended structure can be realized by using the droplet containing the non-gelable liquid as a support.

In some embodiments, the printing tip 3 may employ a glass capillary tube, a quartz capillary tube, a stainless steel capillary tube, or the like.

In a preferred embodiment, the printing needle nozzle 3 is heated and drawn by a quartz capillary or a glass capillary to form a pointed cone shape at the tail end, and the outer wall and the inner wall of the tail end are hydrophobized by silanization treatment or hydrophobization reagent, so that the generation of liquid drops with smaller volume and the reduction of cross contamination are facilitated, and the falling off of the liquid drops in the process of printing the liquid drop network is facilitated.

In some embodiments, the material of the working fluid pool may be glass, Polydimethylsiloxane (PDMS), polymethyl methacrylate (PMMA), which is prepared by a wet etching process, a soft lithography process, a laser engraving process, a machining method, or the like;

in some embodiments, the printing fluid pool may be anchored by a groove array, surface wetting treatment, or the like, i.e., to hold the position of the printed droplet;

in some embodiments, the conduit between the syringe on the syringe pump 1 and the printing needle nozzle 3 may be a Polytetrafluoroethylene (PTFE) hose or the like.

In some embodiments, the amphiphilic molecule in the oil phase may be a phospholipid molecule, such as phosphatidylcholine (phosphatidyl choline), 1, 2-diphytane-sn-glycero-3-phosphorylcholine (DPhPC), 1, 2-dioleoylphosphate-sn-glycero-3-phosphorylcholine (DOPC), 1, 2-dipalmitoyl-sn-glycero-3-phosphorylcholine (DPPC), or some other surfactant, and the oil phase solvent used may be hexadecane, silicone oil AR20, mixtures thereof, and the like.

In some embodiments, the method of the present invention comprises the following two steps, "droplet network printing-microgel network solidification", wherein droplet network printing comprises two steps, i.e., "droplet sequence generation-droplet printing":

step 1.1: droplet sequence generation: including the generation and sequencing of droplets to form a predetermined sequence of droplets of different material composition and volume. In the step of generating the liquid drop sequence, the printing needle nozzle can sequentially suck different liquid phases with certain volumes in different stock solution pools continuously, so that the mixing operation of the different liquid phases according to different proportions is realized, and mixed liquid drops are generated.

Step 1.2: droplet printing: positioning the droplets to predetermined positions forms a three-dimensional assembly of droplet stacks, i.e. a three-dimensional patterned droplet network. The method comprises the steps of realizing patterning of a liquid drop network in a liquid drop printing step, realizing position distribution of liquid drops and construction of a three-dimensional liquid drop stacking structure through positioning and spatial arrangement of the liquid drops, firstly adjusting and calibrating the horizontal position of a working liquid pool and the angle position relative to a printing needle nozzle through a calibration platform, measuring the position of an original point, setting a printing coordinate system, then controlling the positioning of the printing needle nozzle in the printing liquid pool of the working liquid pool through a three-axis translation device, and then extruding and placing the liquid drops to a preset position through a liquid bidirectional driving device. Wherein, one liquid drop is contacted with at least one other adjacent liquid drop, and a bilayer of amphiphilic molecules is formed at the contact position of the liquid drops, so that the liquid drop connection and the liquid encapsulation are realized. In this way, a three-dimensionally patterned network of droplets is formed.

Step 2: curing the microgel network: the gelation of the liquid drops containing the hydrogel prepad liquid and the connection between hydrogel microspheres are realized by reaching the condition of the gelation of the liquid drops, thereby forming a three-dimensional microgel network which is assembled by taking hydrogel microparticles with different material components as building units and has certain patterning, namely a three-dimensional patterned multi-material hydrogel heterostructure.

The background of the present invention may contain background information related to the problem or environment of the present invention and does not necessarily describe the prior art. Accordingly, the inclusion in the background section is not an admission of prior art by the applicant.

The foregoing is a more detailed description of the invention in connection with specific/preferred embodiments and is not intended to limit the practice of the invention to those descriptions. It will be apparent to those skilled in the art that various substitutions and modifications can be made to the described embodiments without departing from the spirit of the invention, and these substitutions and modifications should be considered to fall within the scope of the invention. In the description herein, references to the description of the term "one embodiment," "some embodiments," "preferred embodiments," "an example," "a specific example," or "some examples" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Various embodiments or examples and features of various embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction. Although embodiments of the present invention and their advantages have been described in detail, it should be understood that various changes, substitutions and alterations can be made herein without departing from the scope of the claims.