The present invention relates to a cryo formulation-based microneedle device for transdermal delivery of bioactive therapeutic agents, in particular, but not limited to transdermal delivery of vaccines such as mRNA antigens.
Delivery of bioactive agents is of great potential for treatment skin diseases. For example, melanocyte suspensions have been used clinically to vitiligo. Intradermal injection of fibroblast or mesenchymal stem cell was used for wound healing in recessive dystrophic epidermolysis bullosa.
In addition to treat skin diseases, transplantation of cells is also used in the field of facelift and hair regeneration. For example, injection of fibroblast can help restore the elasticity of skin and reduce winkles because fibroblasts can produce a large amount of collagen which can recover skin.
In accordance with a first aspect the present invention, there is provided a cryo formulation-based microneedle device for transdermal delivery of bioactive therapeutic agents, comprising: one or more microneedle patches each including an array of miniaturized needles, wherein each miniaturized needle defining a base end and a tip; and a substrate to which the base end of the array of miniaturized needles is attached or integrated thereto; wherein the microneedle patch is in a cryo status; wherein each of the one or more microneedle patch is adapted to be applied on a skin surface, in which the miniaturized needles penetrates into skin; wherein the miniaturized needles is further arranged to melt so as to release one or more bioactive therapeutic agents into the skin to achieve a targeted therapeutic effect; and wherein the bioactive therapeutic agents includes protein and/or antigens.
In an embodiment the first aspect, each of the one or more microneedle patches consisting of a matrix solution and the bioactive therapeutic agents.
In an embodiment the first aspect, the matrix solution consists of an aqueous base solution and a cryoprotectant.
In an embodiment the first aspect, the aqueous base solution comprises at least one of water, phosphate-buffered saline (PBS), and 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid (HEPES).
In an embodiment the first aspect, the cryoprotectant include at least one of dimethyl sulfoxide (DMSO), glycerol, ethylene glycol, sucrose, fructose, trehalose, galactose, dextrose and proteins.
In an embodiment the first aspect, the cryoprotectant include at least one of poly(ethylene glycol) (PEG), polyvinylpyrrolidone (PVP), polyvinyl alcohol (PVA), poly-l-lysine, hyaluronic acid (HA), starch, gelatin, agarose, alginate, chitosan, cellulose, carboxymethyl cellulose (CMC), collagen, chitin, dextran, guar gum, pullulan, xanthan, xyloglucan, heparin, chondroitin, keratan, mucin, and their derivatives thereof.
In an embodiment the first aspect, the matrix solution further comprises hyaluronic acid and/or a buffered solution.
In an embodiment the first aspect, wherein the buffered solution includes phosphate buffered saline (PBS).
In an embodiment the first aspect, the antigens includes mRNA antigens.
In an embodiment the first aspect, the antigens includes spike glycoprotein (S protein) and/or nucleocapsid protein (NP).
In an embodiment the first aspect, the bioactive therapeutic agents further comprises an mRNA carriers.
In an embodiment the first aspect, the mRNA carriers include polyethylenimine (PEl) and/or protamine.
In accordance with a second aspect the present invention, there is provided a method of fabricating a microneedle device in the first aspect, comprising the steps of: casting the matrix solution containing the bioactive therapeutic agents into a mold defined with an array of microneedle structures; freezing the solution to define the array of microneedle structures on the microneedle patches; and dethatching the microneedle patches from the mold; and storing the microneedle patches below -80° C.
In an embodiment the second aspect, the mold includes a PDMS mold or a metal mold.
In an embodiment the second aspect, the method further comprises the step of urging the bioactive therapeutic agents and/or the matrix solution into the array of microneedle structures define on the mold.
In an embodiment the second aspect, the bioactive therapeutic agents and/or the matrix solution are driven into the mold using centrifugation.
In an embodiment the third aspect, there is provided a method of using the microneedle device of the first aspect, comprising the step of: removing the microneedle device from a storage place at a temperature of below -80° C.; and applying the microneedle device within a predetermined period of time after removal from the storage place.
In an embodiment the third aspect, the predetermined period of time is 30 seconds.
In an embodiment the third aspect, the microneedle patches are arranged to facilities a predetermined penetration depth of the bioactive therapeutic agents into the skin.
In an embodiment the third aspect, the predetermined penetration depth is 50 – 1000 µm.
In an embodiment the third aspect, the method further comprises the step of temporally attaching the microneedle device to a handle, thereby allowing an operator to apply the microneedle device by holding the handle.
The term “comprising” (and its grammatical variations) as used herein are used in the inclusive sense of “having” or “including” and not in the sense of “consisting only of”.
It should be understood that alternative embodiments or configurations may comprise any or all combinations of two or more of the parts, elements or features illustrated, described or referred to in this specification.
Any reference to prior art contained herein is not to be taken as an admission that the information is common general knowledge, unless otherwise indicated. It is to be understood that, if any prior art information is referred to herein, such reference does not constitute an admission that the information forms a part of the common general knowledge in the art, in any other country.
As used herein, the term “and/or” includes any and all possible combinations or one or more of the associated listed items, as well as the lack of combinations when interpreted in the alternative (“or”).
To those skilled in the art to which the invention relates, many changes in construction and widely differing embodiments and applications of the invention will suggest themselves without departing from the scope of the invention as defined in the appended claims. The disclosures and the descriptions herein are purely illustrative and are not intended to be in any sense limiting. Where specific integers are mentioned herein which have known equivalents in the art to which this invention relates, such known equivalents are deemed to be incorporated herein as if individually set forth.
The patent or application file contains at least one drawing executed in color. Copies of this patent or patent application publication with color drawing(s) will be provided by the Office upon request and payment of the necessary fee.
Details and embodiments of the indoor navigation method and system will now be described, by way of example, with reference to the accompanying drawings in which:
The inventors, through their own research, trials and experiments, devised that microneedles (MNs) are an array of miniaturized needles down to the micrometer scale and they are initially developed for transdermal delivery of drugs and vaccines. They allow for the minimally-invasive perturbation of the stratum corneum barrier and controlled and targeted delivery of therapeutic agents in pain-free and blood-free fashion. Recently, they are also used for the extraction of blood and interstitial fluid for biomarker analysis. MN-based devices have low risk of infection, needle-phobic and needle-stick injury and cross-contamination.
In some example embodiments, MNs may be made of silicon, metals (e.g. stainless-steel and titanium), ceramics, and polymers. However, silicon, metal and ceramics based MNs suffer from the limited drug loading, potential break-up in skin, or complicated and expensive fabrication procedures, and polymer MNs are limited by the low drug loading and inability to maintain the activity and deliver fragile active agents such as protein, plasmid, stem cells, immune cells, bacteria, and virus.
In accordance with an embodiment of the present invention, there is provided a new class of MN device, the cryo formulation-based MN device (cryo MNs, or ice MNs), which is significantly different from the abovementioned MN platforms in terms of materials, formulations, and fabrication protocols.
Preferably, this device is made of aqueous solutions and bioactive therapeutic agents (eg. cells, drugs, and proteins, et al.) and fabricated by freezing to form the cryo status. The formulation is optimized to maximize the bioactivity of therapeutic agents while providing sufficient mechanical properties for the ice MNs to penetrate into the skin layers. Finally, the ice MNs are usually made right before usage within the template (can be less than 4 hours), but can be stored for at least 1 month without loss of bioactivity or viability.
In one example embodiment, the invention provides a direct integration of cells and delivery of cells with ice MNs. The inventors devise that all other MN platforms except hollow MNs are not suitable for cell delivery, and although hollow MNs may be used to deliver cells through pressure-based injection, such system lacks of control of the injection depth, cell number, and pattern of cells.
Preferably, the ice MNs is the first type of solid MN that can deliver cells and directly integrate cells into MNs. It offers a convenient strategy to control the location, density and types of delivered cells in skin.
With refernece to
In this example, the microneedle patches 102 consisting of a matrix solution containing a bioactive therapeutic agents being freezed in the solid state, such that when the ice microneedle patches 102 is subjected to heat at the skin surface 108 and/or from the environment, it melts gradually and hence the bioactive therapeutic agents is released into the skin as the patch 102 melts.
Examples of bioactive therapeutic agents may includes biological cells, such as but not limited to cancer cells, fibroblasts, endothelial cells, smooth muscle cells, stem cells, melanocytes, dendritic cells, neutrophils, and T-cells. Alternativley or additionally, the bioactive therapeutic agents may include other biochemical substances such as but not limited to drugs, vaccines, proteins, peptides, nucleic acids, bacteria, virus and fungi.
The bioactive therapeutic agents may be contained in a matrix solution, comprising an aqueous base solution and a cryoprotectant, such that the matrix solution and the bioactive therapeutic agents may be molded to have the shape of the microneedles 104 with the base. Examples of the aqueous base solution includes one or more of water, phosphate-buffered saline (PBS), and 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid (HEPES), and these aqueous base solution may be solidified upon freezing.
For example, the ice-MNs that were finally frozen either in -80° C. or liquid nitrogen (LN) were named as ice-MNs (-80° C.) and ice-MNs (LN), respectively. The morphology of ice MNs 104 is shown in the
The formulation of solution for preparing ice MN depends on the desired active agents that will be delivered. The following table lists a number of example choice of several freezing solutions for different active agents.
With reference to
Optionally, the method further comprises the step of urging the bioactive therapeutic agents and/or the matrix solution into the array of microneedle structures define on the mold, such as by using centrifugation.
Take 2.5%wt DMSO combined with 100 mN sucrose as an example, to fabricate ice MNs 104 for cell delivery, at step 202, the mold defining the shape of the needles may be filled up with the freezing media, such as the matrix solution or the mixture of 2.5%wt DMSO combined with 100 mM sucrose. At step 204, cells contained in a freezing solution such as water and/or the cryoprotectants are casted to the mold at the base. At step 206, the cells are driven into the needle structures using centrifugation. At step 208, the residues of cell suspension from the base may be discarded, and then the base of the mold may be refilled to form the base of the MN device. At step 210, the matrix solution and the cells are frozen below the melting point of the matrix solution, e.g. at -20° C., followed by demolding the frozen patch after solidification. Finally, at step 212, the fabricated cryo formulation-based microneedle device may be stored under -80° C. and/or any other suitable environment, such as in liquid nitrogen, for long-time storage if necessary.
In an alternative example, to fabricate ice MNs for small molecular drug delivery, small molecular drug may be dissolved in aqueous with desired concentrations. The prepared solution is casted into PDMS mold and followed by centrifugation. Then the PDMS mold is put at -20° C. for 2 hours and then transferred to -80° C. Then Ice MN integrated with small molecular drugs can be peeled out of PDMS mold before applications.
Alternatively, to fabricate ice MNs for proteins/peptides delivery, proteins/peptides and BSA (1 mg/mL) may be dissolved in aqueous solution with desired concentrations. The prepared solution is casted into PDMS mold and followed by centrifugation. Then the PDMS mold is put at -20° C. for 2 hours and then transferred to - 80° C. Then Ice MNs integrated with small molecular drugs can be peeled out of PDMS mold before applications.
Yet alternatively, to fabricate ice MNs for DNA/RNA delivery, the DNA/RNA and polycations (1 mg/mL) are dissolved in aqueous solution with desired concentrations. The prepared solution is casted into PDMS mold and followed by centrifugation. Then the PDMS mold is put at -20° C. for 2 hours and then transferred to -80° C. Then Ice MN integrated with small molecular drugs can be peeled out of PDMS mold before applications.
The solutions for making ice MNs consist of aqueous base solutions and cryoprotectants. The aqueous base solutions may include water, PBS, and/or HEPES. The cryoprotectants include DMSO, glycerol, ethylene glycol, sucrose, fructose, trehalose, galactose, dextrose, proteins, or any types of combination of two or more cryoprotectants. The cryoprotectants also include polyvinylpyrrolidone, polyvinyl alcohol, poly-l-lysine, HA, starch, gelatin, agarose, alginate, chitosan, cellulose, collagen, chitin, dextran, guar gum, pullulan, xanthan, xyloglucan, and their derivatives, and the combinations thereof. In addition, the cryoprotectants include the hydrogel systems made from above-mentioned polymers.
To optimize the freezing solution for cell delivery, in an experiment performed by the inventors, six types of cells, including Hela-red fluorescent protein (RFP) stable human cell line (RFP-Hela), human keratinocytes (HACAT), human normal dermal fibroblasts (NDFs), human mesenchymal stem cells (MSCs), human melanocytes and human immune cells (T-cells) were frozen in the solution with different concentration of DMSO and sucrose. The results were shown in
Furthermore, with reference to
For the following experiment, the RFP-Hela loaded ice-MNs (LN) were selected as studying group and directly used after 1-day storage. The ice-MNs can successfully deliver the RFP-Hela into 3D hydrogel system (fake skin model) and the alive RFP-Hela could proliferate in this system, as shown in
With reference to
Preferably, the microneedle patches 102 are arranged to facilities a predetermined penetration depth, such as 50 – 1000 µm, of the bioactive therapeutic agents into the skin.
Optionally, the method further comprises the step of temporally attaching the microneedle device 100 to a handle 702, thereby allowing an operator to apply the microneedle device 100 by holding the handle 702. For example, referring to
In addition, an animal experiment was conducted to evaluate the performance of the apparatus fabricated in accordance with embodiments of the present invention. The RFP-Hela loaded ice MNs can easily penetrate into mice skin by the thumb force. It is clear that there was no harm effects of ice MNs on mice skin as show in
Furthermore, the ice MNs may be applied in clinic applications. The inventors monitored the intensity red fluorescent protein secreted by the delivered RFP-Hela. It demonstrated that the RFP-Hela could survive in mice skin and continued to secrete RFP after being delivered into mice skin by ice MNs as shown in
These embodiments may be advantageous in that, the ice-based MNs may be used in various treatments of skin diseases and facelift by delivering all kinds of drugs and biologics. Example applications include the treatment such as (but not limited to) vitiligo, melanoma, skin regeneration, wound healing, hair regeneration, and anti-wrinkling.
Advantageously, the MN-based device may be applied for loading and transdermal delivery of various types of bioactive therapeutic agents (e.g. therapeutic cells, small molecular drug, proteins/peptides, DNA/RNA, bacteria, virus, fungi, et al.) in a minimally-invasive manner. This device can maintain the viability and bioactivity of loaded therapeutic agents. The device has enough mechanical strength, which ensures the device can penetrate across the stratum corneum and deliver the cargo into the targeted skin layers.
By selecting and loading certain therapeutic agents, the devices can be applied for different biomedical applications, such as cancer immunotherapy (by loading dendritic cells or T cells), treatment of vitiligo (by loading melanocytes), treatment of diabetes (by loading insulin or insulin-secreting cells), treatment of topical infection (by loading probiotic bacteria or bacteriophages) and promoting skin regeneration (by loading fibroblasts or stem cells).
Embodiments of the present invention may also provide the following advantages.
Firstly, the materials of present MNs are aqueous solutions which are readily accessible and easy to prepare. For example, the 2.5% wt DMSO in water or PBS and 200 mM sucrose dissolved in water or PBS. This is different from other MN devices usually made from polymer, metal, silicon and glass, which might involve with expensive raw materials, complex chemical synthesis and potential issue of biocompatibility.
Second, the fabrication process of the device is simpler, compared with the fabrication of solid or hollow MNs.
Third, this present invention integrates living cells into MNs as a ready-to-use device and the cells can maintain alive inside the device for a long-term storage. By harnessing the device according to the embodiments of the present invention, the transdermal delivery of cells can be easily performed without assistance of any extra device. Therefore, application processes can be greatly simplified. This is particularly different from other technologies or example devices for cell delivery which may involve complex and redundant procedures including cell harvest and preparation of cell infusing solution during each administration processes, or may require additional equipment for providing infusion pressure.
Forth, the microneedle patches can also be applied for loading and delivery of many types of bioactive therapeutics, such as drugs, protein/ peptides, nucleic acid, virus and bacterial, et al, for different biomedical purposes, which is different from other examples that only focus on a single type of therapeutics.
In some embodiments, the microneedle patches may specifically made for delivery of protein and mRNA antigens, for example in vaccination applications. However, the inventors devised that mRNA antigen are not suitable to be stored at room temperature, therefore the cryomicroneedle (cryoMN) encapsulating mRNA is more preferably produced and preserved at minus 80° C.
Referring to
At step 1010, a matrix solution without antigen (i.e. HA + PBS solution) may be added to fill the back plate to form a base of the cryomicroneedle patch. Finally, at step 1012, the mold may be frozen at minus 80° C. for 24 hours to solidify the liquid and set the cryomicroneedle patch, followed by demoulding the patch from the PDMS mould.
As appreciated by a skilled person in the art, the formula of the matrix solution, the freezing temperature and or the freezing duration may be changed if necessary, depending of the protein and/or compositions of the bioactive therapeutic agents to be encapsulated in the cryomicroneedles.
After demolding from the PDMS mould, the as fabricated cryomicroneedles device may be stored at minus 80° C. for a long period of time. To use the cryomicroneedles in vaccinations, the cryomicroneedles device may be removed from the storage place; and then may be applied to the target spot of the skin surface within a predetermined period of time after removal from the storage place, similar to the previous examples. Optionally, after pressing the MN patch 102 on the skin surface, the backing part may be removed from the skin surface such that only the tips with the antigens are left in the skin, and the needles further dissolves to release the antigens to the body of the target.
With reference to
The inventors also performed experiments on gel electrophoresis after HA-PBS cryoMN dissolution using Enhanced Green Fluorescent Protein (EGFP) mRNA. With reference to
With reference to
Without wishing to be bound by theory, apart from the conventional SARS-CoV-2 spike glycoprotein (S protein), the nucleocapsid protein (NP) may be an alternative in vaccine applications due to its ability to induce anti-viral cytotoxic T cell responses. NP plays a vital role in viral host cell entry and modulates virus particle assemble and release.
For example, there are many Human Leukocyte Antigen (HLA) binding peptides within NP, which could prime specific CD8+ and CD4+ T cell responses via major histocompatibility complex class 1 (MHC1) and major histocompatibility complex class2 (MHC2) pathways respectively. The specific B cell antibody response post the delivery of NP was studied through the ELISA assay of IgG antibodies in sera against SARS-CoV-2.
The inventors performed further experiments to compared pure HA microneedles at room temperature and HA-PBS cryoMN. There were four groups including subcutaneously injected (S.C.) NP (25 µg/mice), HA-MN delivered NP (25 µg/mice), HA-PBS cryoMN delivered NP (25 µg/mice) and MN-delivered controls. Referring to the plots as shown in
Preferably, the bioactive therapeutic agents further comprises an mRNA carriers, such as polyethylenimine (PEI) and/or protamine. Due to naked mRNA cannot readily cross the cell membrane on its own, a delivery systems to enhance its cell permeation may be required. As described earlier, liposomes may not work very well at -80° C.
Preferably, in the following experiments, polyethylenimine (PEI) and protamine were chosen as mRNA carriers. Among various polymeric carriers for gene delivery, PEI is a material which may be used as a standard control in nucleic acid transfection, and different molecular weight PEI may be added to cryoMN system to increase the efficiency of mRNA delivery. Additionally or alternatively, protamine is a natural cationic protein, which gives it an excellent ability to complex nucleic acid including mRNA and provides increased uptake of mRNA and transfection capabilities.
Advantageously, these two carriers can work as normal at -80° C. Since N protein was used at -80° C. and provided normal ELISA data, protein such protamine will not be broken by low temperature. PEI also has no reason to be broken as a polymer in low temperature. Therefore, these two carriers may be used to deliver our mRNA antigen.
Preferably, luciferase mRNA may be used as a target and injected cryoMN into mouse epidermis. With reference to
As shown in
It will be appreciated by persons skilled in the art that numerous variations and/or modifications may be made to the present invention as shown in the specific embodiments without departing from the spirit or scope of the invention as broadly described. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive.
Any reference to prior art contained herein is not to be taken as an admission that the information is common general knowledge, unless otherwise indicated.
Number | Date | Country | |
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0033564 A1 | Feb 2023 | US |
Number | Date | Country | |
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63071491 | Aug 2020 | US |