Recent advances in microneedles-mediated transdermal delivery of protein and peptide drugs

✅ 全文

微针介导的蛋白多肽药物经皮递送研究进展

作者 Ting Liu; Minglong Chen; Jintao Fu; Ying Sun; Chao Lü; Guilan Quan; Xin Pan; Chuanbin Wu 期刊 Acta Pharmaceutica Sinica B 发表日期 2021 ISSN 2211-3835 DOI 10.1016/j.apsb.2021.03.003 类型 原创研究 (Original Research)

📄 中文摘要 Chinese Abstract

中文
蛋白质和多肽因其在治疗多种疾病方面的高效能和高特异性,已成为重要的治疗性药物。然而,其临床应用受到诸多挑战的限制,如分子量大、稳定性差以及对酶降解的敏感性,这些因素阻碍了它们有效穿越皮肤等生物屏障。注射仍是主要的给药途径,但由于疼痛、不便以及针头重复使用带来的安全性问题,常导致患者依从性较差。经皮给药提供了一种无创替代方案,但大多数蛋白质和多肽药物无法有效穿透角质层。微针(MNs)作为一种微创技术,近年来受到广泛关注,它可在皮肤中形成可逆的微通道,实现大分子的高效经皮递送,同时提高患者的舒适度和安全性。

📋 英文结构化总结 English Structured Summary

全文整理

EN

Background:

Proteins and peptides have emerged as important therapeutic agents due to their high potency and specificity in treating various diseases. However, their clinical use is limited by challenges such as large molecular weight, poor stability, and susceptibility to enzymatic degradation, which hinder effective delivery across biological barriers like the skin. Injection remains the primary administration route, but it often leads to poor patient compliance due to pain, inconvenience, and safety concerns related to needle reuse. Transdermal drug delivery offers a noninvasive alternative, yet most protein and peptide drugs cannot penetrate the stratum corneum effectively. Microneedles (MNs) have recently gained attention as a minimally invasive technology capable of creating reversible microchannels in the skin, enabling efficient transdermal delivery of macromolecules while improving patient comfort and safety.

Methods:

This review synthesizes recent advances in microneedle-mediated transdermal delivery of protein and peptide drugs, based on full-text analysis of the original research article. The authors categorized MNs into five types—solid, coated, hollow, dissolving, and hydrogel-forming—and described their fabrication methods, materials, and mechanisms of drug delivery. Emphasis was placed on how each MN type accommodates the sensitivity of proteins and peptides to environmental stressors such as temperature, pH, and organic solvents. The review also summarizes preclinical and emerging clinical applications of MNs in infectious diseases, diabetes, cancer, and other conditions, highlighting key studies and technological innovations. No new experimental data were generated; the methodology is purely analytical and literature-based.

Results:

Microneedles have demonstrated significant potential for delivering a wide range of protein and peptide therapeutics. Solid MNs enhance skin permeability through pretreatment, while coated MNs allow direct deposition of drugs upon insertion. Hollow MNs enable controlled, high-dose delivery via pressure-driven flow, and dissolving MNs offer one-step administration with biocompatible matrices that protect drug stability. Hydrogel-forming MNs swell upon insertion, facilitating sustained release without leaving residues. Notably, MNs have been successfully used to deliver vaccines (e.g., influenza, hepatitis B), insulin for diabetes, and immunotherapies for cancer, often achieving immune responses or pharmacological effects comparable to or better than subcutaneous injections. Innovations such as glucose-responsive MNs for closed-loop insulin delivery and active MNs with built-in propulsion systems for deeper tissue penetration have further expanded their functionality.

Data Summary:

Studies cited show that MNs can achieve bioavailability similar to subcutaneous injection—for example, Peptide A delivered via coated MNs showed comparable bioavailability to injection. In vaccine applications, 0.5 μg of antigen delivered by MNs induced immune responses equivalent to 5 μg given intramuscularly. Dissolving MNs retained full enzymatic activity of proteins when fabricated under mild conditions, and some formulations maintained vaccine immunogenicity after 24 months at 25 °C. In diabetes models, insulin-loaded dissolving MNs produced hypoglycemic effects nearly identical to subcutaneous injections. Active MNs delivering aCTLA-4 resulted in 60% of melanoma-bearing mice being tumor-free, compared to no long-term survival in passive MN groups.

Conclusions:

Microneedles represent a promising platform for the transdermal delivery of protein and peptide drugs, overcoming key limitations of conventional injection therapies. Their minimally invasive nature, ease of self-administration, ability to preserve drug stability, and potential for controlled or responsive release make them suitable for chronic disease management and vaccination. The versatility of MN designs—especially dissolving and hydrogel-forming types—enables tailored delivery strategies for diverse therapeutic agents. While challenges remain in scaling up manufacturing and ensuring mechanical robustness, ongoing innovations in materials science and microfabrication continue to advance the field toward clinical translation.

Practical Significance:

The real-world impact of microneedle technology lies in its potential to replace or supplement injections for conditions requiring frequent dosing, such as diabetes and chronic infections, thereby improving patient adherence and reducing healthcare burdens. MNs could enable pain-free, self-administered vaccination campaigns, particularly in resource-limited settings, and support personalized cancer immunotherapy through localized, sustained delivery of checkpoint inhibitors. Additionally, their compatibility with cold-chain-free storage enhances global vaccine distribution logistics, making them a transformative tool in public health and precision medicine.

📋 中文结构化总结 Chinese Structured Summary

中文

背景:

蛋白质和多肽因其在治疗多种疾病方面的高效能和高特异性,已成为重要的治疗性药物。然而,其临床应用受到诸多挑战的限制,如分子量大、稳定性差以及对酶降解的敏感性,这些因素阻碍了它们有效穿越皮肤等生物屏障。注射仍是主要的给药途径,但由于疼痛、不便以及针头重复使用带来的安全性问题,常导致患者依从性较差。经皮给药提供了一种无创替代方案,但大多数蛋白质和多肽药物无法有效穿透角质层。微针(MNs)作为一种微创技术,近年来受到广泛关注,它可在皮肤中形成可逆的微通道,实现大分子的高效经皮递送,同时提高患者的舒适度和安全性。

方法:

本综述基于对原始研究论文的全文分析,综合了微针介导的蛋白质和多肽药物经皮递送领域的最新进展。作者将微针分为五种类型——固体微针、涂层微针、空心微针、可溶性微针和水凝胶微针,并分别描述了其制备方法、所用材料及药物递送机制。重点探讨了每种微针类型如何适应蛋白质和多肽对环境应激因素(如温度、pH值和有机溶剂)的敏感性。综述还总结了微针在传染病、糖尿病、癌症及其他疾病中的临床前和新兴临床应用,重点介绍了关键研究和技术创新。本研究未产生新的实验数据,方法纯属分析和文献综述性质。

结果:

微针已展现出递送多种蛋白质和多肽治疗药物的巨大潜力。固体微针通过预处理增强皮肤通透性,涂层微针可在插入时直接沉积药物。空心微针通过压力驱动实现可控的高剂量递送,可溶性微针则利用生物相容性基质实现一步给药,同时保护药物稳定性。水凝胶微针在插入后膨胀,促进持续释放且不留残留物。值得注意的是,微针已成功用于递送疫苗(如流感疫苗、乙肝疫苗)、糖尿病用胰岛素以及癌症免疫疗法,其引发的免疫反应或药效常与皮下注射相当甚至更优。葡萄糖响应型微针用于闭环胰岛素递送,以及内置推进系统的主动型微针用于深层组织穿透等创新技术,进一步拓展了微针的功能。

数据总结:

引用的研究表明,微针可实现与皮下注射相当的生物利用度——例如,通过涂层微针递送的肽A显示出与注射相当的生物利用度。在疫苗应用中,0.5 μg抗原经微针递送可诱导与5 μg肌肉注射相当的免疫反应。在温和条件下制备的可溶性微针保留了蛋白质的全部酶活性,部分制剂在25 °C下保存24个月后仍保持疫苗免疫原性。在糖尿病模型中,载胰岛素可溶性微针产生的降糖效果与皮下注射几乎相同。主动型微针递送aCTLA-4后,60%的黑色素瘤小鼠实现无肿瘤生存,而被动型微针组无长期存活。

结论:

微针代表了蛋白质和多肽药物经皮递送的有前景平台,克服了传统注射疗法的关键局限性。其微创特性、易于自我给药、保持药物稳定性以及可控或响应性释放的潜力,使其适用于慢性病管理和疫苗接种。微针设计的多样性——尤其是可溶性和水凝胶型——为不同治疗药物提供了定制化的递送策略。尽管在规模化生产和确保机械强度方面仍存在挑战,材料科学和微加工领域的持续创新正推动该领域向临床转化迈进。

实际意义:

微针技术的现实意义在于其有望替代或补充需要频繁给药的疾病(如糖尿病和慢性感染)的注射治疗,从而提高患者依从性并减轻医疗负担。微针可实现无痛、自我给药的疫苗接种,尤其在资源有限的环境中具有优势,并通过局部持续递送检查点抑制剂支持个性化癌症免疫治疗。此外,其与无冷链储存的兼容性增强了全球疫苗分发物流,使其成为公共卫生和精准医疗领域的变革性工具。

📖 英文全文 English Full Text

EN

2814 apsb Acta Pharmaceutica Sinica. B Acta Pharm Sin B Elsevier PMC8424228 8424228 8424228 34522590 10.1016/j.apsb.2021.03.003 Recent advances in microneedles-mediated transdermal delivery of protein and peptide drugs Liu Ting a Chen Minglong a Fu Jintao a Sun Ying a Lu Chao b Quan Guilan b ∗ Pan Xin a ∗ Wu Chuanbin b a School of Pharmaceutical Sciences, Sun Yat-sen University, Guangzhou 510006, China b College of Pharmacy, Jinan University, Guangzhou 510632, China ∗ Corresponding authors. Tel./fax: +86 20 39943427. xiaoplanet@163.com panxin2@mail.sysu.edu.cn 10 3 2021 11 8 2326 2326–2343 13 9 2021 © 2021 Chinese Pharmaceutical Association and Institute of Materia Medica, Chinese Academy of Medical Sciences. Production and hosting by Elsevier B.V. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/). Abstract Proteins and peptides have become a significant therapeutic modality for various diseases because of their high potency and specificity. However, the inherent properties of these drugs, such as large molecular weight, poor stability, and conformational flexibility, make them difficult to be formulated and delivered. Injection is the primary route for clinical administration of protein and peptide drugs, which usually leads to poor patient's compliance. As a portable, minimally invasive device, microneedles (MNs) can overcome the skin barrier and generate reversible microchannels for effective macromolecule permeation. In this review, we highlighted the recent advances in MNs-mediated transdermal delivery of protein and peptide drugs. Emphasis was given to the latest development in representative MNs design and fabrication. We also summarize the current application status of MNs-mediated transdermal protein and peptide delivery, especially in the field of infectious disease, diabetes, cancer, and other disease therapy. Finally, the current status of clinical translation and a perspective on future development are also provided. Keywords: Microneedles, Transdermal drug delivery, Proteins, Peptides, Infectious diseases, Diabetes, Cancer, Clinic Graphical abstract Proteins and peptides have become a significant therapeutic modality for various diseases, and microneedles provide a great prospect for the transdermal delivery of proteins and peptides. Image 1 status released display-pdf yes is-olf no is-manuscript no is-preprint no is-journal-matter no is-scanned no is-retracted no Received 2020 Aug 23; Revised 2020 Nov 12; Accepted 2020 Dec 8; Issue date 2021 Aug. 1. Introduction Proteins and peptides exhibit the most prominent effects in human body, such as molecular transportation, biological scaffold, cellular regulation, and enzymatic catalysis, which have played an important role in almost every medical field 1 , 2 , 3 , 4 . Insulin was the first therapeutic protein approved in 1982 and since then remarkable progress has been achieved in the clinical application of numerous protein and peptide therapeutics 5 , 6 . However, the application of protein and peptide drugs is commonly restrained by certain limitations. The large molecular weight of these drugs substantially decreases their permeability capacity across biological barriers such as skin and mucous membranes. Besides, loss of biological activity in response to external conditions (moisture and temperature) and endogenous proteolytic enzyme put a high difficulty on formulation and delivery technologies 7 . Currently, injection is the primary route for clinical administration of protein and peptide drugs. Intravenous, subcutaneous, and intramuscular injection are the most widely used ways for delivering protein and peptide drugs 2 , 8 , 9 , 10 , 11 , 12 . Regardless of the injection method, most protein and peptide drugs are easily degraded by various metabolic enzymes in the body, resulting in short half-life in vivo , which means frequent injections are required. Furthermore, injection therapy is inconvenient and unfriendly, especially for patients with chronic diseases such as rheumatoid arthritis and diabetes. Injection safety should also be considered, since contamination of needles during administration can lead to transmission of some infectious diseases such as Hepatitis B and C. Therefore, for the delivery of protein and peptide drugs, there is a great need for an alternative drug delivery system that can be readily administrated with improved therapeutic efficacy, good patient compliance, and safety. Transdermal drug delivery is a choice that delivers biologically active agents through skin portals for local or systemic effects, which is noninvasive and can be self-administered 13 . There are some requirements for the drugs suitable for transdermal administration, such as a maximum molecular weight of 1000 Da, and a balance between hydrophobicity and polarity due to the stratum corneum barrier 14 . Most protein and peptide drugs are hydrophilic and macromolecular in nature, and therefore they cannot easily penetrate into the skin. Over the past a few decades, various chemical and physical methods such as penetration enhancers 15 , microjet 16 , laser 17 , electroporation 18 , sonophoresis 19 , and iontophoresis 20 have been developed as feasible strategies to improve transdermal drug permeation. But these techniques are usually expensive and cumbersome to use, and still exhibit limited efficiency for successful transdermal delivery of macromolecular drugs. Recently, microneedles (MNs) have become a new type of drug delivery technique, and the applications of MNs have been extended to various aspects, including small chemical molecules 21 , 22 , vaccines 23 , 24 , genes 25 , proteins 4 , 26 , and nanoparticles 27 . Particularly, MNs provide a great prospect for the transdermal delivery of proteins and peptides 28 , 29 . MNs are minimally invasive device with needles (<1 mm) arranged orderly on the base. They can directly penetrate the stratum corneum by generating reversible microchannels in the skin. These microchannels can grant access of drugs to the dermal microcirculation located in the interior layers of the skin ( Fig. 1 ). Compared with injection, MNs will not contact with blood vessels and nerves in the deep dermis, which provide better patient compliance and favorable safety profile. Moreover, the mild fabrication condition of MNs will not impact the biological activity of proteins and peptides. Figure 1 Schematic illustration of protein and peptide drug delivery by conventional injections and microneedles. Figure 1 This review provides comprehensive updates on MNs-mediated transdermal delivery of protein and peptide drugs. Emphasis was given to the latest development and advance in representative MNs design and fabrication. Additionally, we summarized the recent studies about the applications of MNs-mediated protein and peptide delivery, particularly focusing in the field of infectious disease, diabetes, cancer, and other disease therapy. Finally, the current status of clinical translation and a perspective on future development were also provided. 2. Representative types of MNs Gerstel et al. proposed the concept of MNs in 1971, and Henry et al. 30 firstly reported the utilization of MNs for transdermal drug delivery in vivo in 1998 30 , 31 . Since then, various types of MNs have been successfully developed 32 . Based on different drug delivery strategies, MNs can be generally classified into five categories, including solid MNs, coated MNs, hollow MNs, dissolving MNs, and hydrogel-forming MNs ( Fig. 2 ). Each type of MNs has been extensively studied for transdermal drug delivery. However, the protein and peptide drugs are usually sensitive to high temperature, pH value, and organic solvents compared with inert small molecules 33 . To avoid the damage of their biological activity, it is necessary to understand the properties of each type of MNs, and then select reasonable MNs types to formulate them. In this section, the typical applications associated with different MNs-mediated delivery approaches are described in detail. Figure 2 Representative types of MNs for transdermal drug delivery. Figure 2 2.1. Solid MNs Solid MNs usually need a two-step operation for drug delivery. Briefly, solid MNs are first inserted into the skin and subsequently removed to form temporary microchannels. Then, a suitable pharmaceutical dosage form (such as gel, cream, or ointment) is applied to the previously formed microchannels 23 , 34 . Solid MNs should offer sufficient mechanical strength for successful skin pretreatment by selecting the materials of MNs 23 . Typically, solid MNs are fabricated from silicon 35 and metal 36 , 37 . It is worth noting that silicon and metal have good properties for solid MNs fabrication, but they may be unsuitable for transdermal drug delivery. Their non-biodegradable nature may cause safety issues after being inserted into the skin. In contrast, polymeric materials usually have good biocompatibility. Various polymeric materials, such as polylactic acid (PLA), polymethylmethacrylate, polycarbonate, and carboxymethylcellulose (CMC) have been developed to prepare solid MNs as an alternative to non-biodegradable metal or silicon 38 , 39 , 40 . Solid MNs deliver drugs by passive diffusion through the generated microchannels in the skin. Therefore, the length and density design of solid MNs used for skin pretreatment will affect drug penetration 41 , 42 . Moreover, the properties of the drugs also affect delivery efficiency. Contrary to the traditional transdermal delivery, the microchannels formed by the pretreatment of solid MNs will increase the penetration of hydrophilic compounds 43 . McAllister et al. 44 demonstrated that the permeation of bovine serum albumin (BSA) and insulin was increased after skin pretreatment using solid silicon MNs. The molecular weight of drugs can also affect passive transport by using solid MNs 45 , 46 . Verbaan et al. 46 observed that the transport rate of the larger molecular weight (72 kDa) compound was much lower than the compounds with molecular weight of 10 kDa and 538 Da. Solid MNs have some inherent drawbacks. A two-step administration process including pretreatment with MNs array and then application of pharmaceutical preparations is considered inconvenient, and it may cause imprecise dosage 47 . Due to the negative impact on patient compliance, drug delivery strategies based on other MNs have now become more prevalent. 2.2. Coated MNs To avoid a two-step application process, solid MNs are coated with drugs on the surface of the needles to obtain coated MNs. Coated MNs provide a more convenient and controllable way for transdermal drug delivery. When coated MNs are inserted, the drug coating layer will dissolve and further deposit the active pharmaceutical ingredients into the skin, then the MNs can be removed 48 . Coated MNs are typically prepared from metal or silicon. To avoid the use of less biocompatible materials, polymeric coated MNs have also been widely investigated. The solid microstructure transdermal system (sMTS) is prepared by a strong polymer, which can retain its structural integrity upon insertion into the skin 49 , 50 , 51 . Kapoor et al. 51 developed the coated sMTS for Peptide A delivery. Two hundred and fifty micrograms of Peptide A were coated on a patch containing 316 needles. The successful transdermal delivery was achieved with the bioavailability being similar to the subcutaneous injection. Besides, the stability of peptide A was significantly improved when coated on the sMTS 51 . Several techniques, such as spray coating, dip coating, and piezoelectric inkjet printing, were applied for the coating of MNs 52 . The spray coating and dip coating are the most common methods using an aqueous drug solution with high viscosity to retain more drugs on MNs surface. The main challenge is how to ensure sufficient therapeutic agents are uniformly coated. Therefore, it is important to optimize the coating process and formulation composition. Surfactants, viscosity enhancers, and peptide stabilizers are usually required in the formulations, to ensure coating stability and uniformity of the drugs 53 . Since most biomolecules are hydrophilic, the coating solution is usually aqueous. Zhao et al. 54 developed a coating formulation, which contained ternary co-solvents and polyvinyl alcohol 2000, for both hydrophilic and hydrophobic peptide loading with maintained bioactivity. Other methods such as layer-by-layer technique are also effective in MNs coating. In this approach, drug molecules can be coated onto MNs by alternately dipping into two solutions containing oppositely charged solutes to form a polyelectrolyte multilayers 55 . Although the mechanical strength of coated MNs is usually retained, their tip sharpness is reduced with the drug loading, which may influence the skin penetration ability 56 . Therefore, the drug loading amount of coated MNs is compromised, which indicates that proteins and peptides with high potency are suitable for this strategy, such as desmopressin 56 , human growth hormone 57 , and interferon alpha 58 . 2.3. Hollow MNs Hollow MNs are sub-millimeter devices acted like micron-scale syringes, which can penetrate the stratum corneum to allow the flow of liquid formulation into the epidermis or dermis 59 . In the simplest form, drug delivery using hollow MNs is achieved through passive diffusion. Since the passive diffusion rate in dense tissues is relatively low, faster transport rate through pressure-driven flow or diffusion has been successfully achieved 21 , 47 . Consequently, compared with solid MNs, hollow MNs can allow the administration of larger doses, and simultaneously provide an exact transport rate 21 , 60 , 61 , 62 . The digitally controlled hollow MNs injection system (DC-hMN-iSystem) can provide accurate amount of therapeutic vaccine. Immunization study in mice showed that HPV peptide vaccine delivered through the DC-hMN-iSystem induced powerful cytotoxic and T helper response 63 . Hollow MNs-mediated intradermal delivery of nanoparticles is also an effective strategy to improve the effectiveness of vaccine. Antigen-loaded poly( d , l -lactide-glycolide) nanoparticles delivered via hollow MNs elicited a remarkably higher antibody response and more lymphocytes than intramuscular injection and soluble antigen delivered via hollow MNs 64 . Hollow MNs usually need a more complicated fabrication technology. In addition to preparing a needle with suitable inner holes, hollow MNs should also be combined with some form of drug reservoir. Hollow MNs are usually prepared from metal or silicon with different inner hole diameters, which are inherently weaker than solid MNs and have a greater risk of breakage 65 . 2.4. Dissolving MNs Dissolving MNs are usually prepared from dissolvable materials with therapeutic agents incorporated into the needles, which can effectively deliver drugs into the skin by the dissolution of needle matrix 66 , 67 , 68 . Many materials have been used to prepare dissolving MNs, from low molecular weight carbohydrates to high molecular biodegradable polymers, including dextran, CMC sodium, hyaluronic acid (HA), chondroitin sulfate, polyvinylpyrrolidone (PVP), and polyvinylalcohol (PVA). The use of dissolving MNs is also a one-step administration that is pretty compliant for patients. Dissolving MNs have the unique advantages that they leave no harmful material and do not generate biohazardous sharp waste after application 69 , 70 , 71 . In addition, the mild preparation condition of dissolving MNs makes industrialization easier to achieve, which is quite beneficial to protein and peptide drugs. The solid state of the encapsulated biomolecules can also protect them from cold chain storage and transport 72 . Various methods such as micromolding 73 , drawing lithography 74 , droplet-borne air blowing 75 , electro-drawing 76 , and photolithography 77 have been developed for fabricating dissolving MNs. Micromolding method is most widely adopted. Briefly, micromolds are filled by polymer melt or solvent casting, sometimes with the additional use of vacuum and/or centrifugal force. Then the molds are allowed to solidify or in situ polymerize of liquid in the microcavities 23 . It should be noted that the abovementioned methods are usually only suitable for the small-scale preparation of MNs in academic field. For scale-up fabrication, several novel techniques have been designed to manufacture dissolving MNs in a highly effective, controllable, and scalable way 78 . The double-penetration female mold-based positive-pressure microperfusion technique was also developed by our group 79 for scale-up fabrication of dissolving MNs 79 . Heat-sensitive proteins and peptides should be encapsulated in micromolds and solidified at mild conditions that will not destroy their activity. Park et al. 80 fabricated poly-lactide -co- glycolide (PLGA) MNs using the micromolding method to encapsulate microparticles containing BSA and calcein. They proved the feasibility of the controlled release of calcein and BSA using polymeric MNs 80 . However, due to the use of elevated temperature in processing, protein activity had a slight loss. To address this issue, Lee et al. 69 employed milder preparation condition to fabricate dissolving MNs from ultra-low viscosity CMC with the full enzymatic activity. Similarly, erythropoietin loaded dissolving MNs were prepared using a thread-forming polymer as a base at room temperature 81 . Although dissolving MNs have significant advantages in transdermal drug delivery, it is hard to control the amount and localization of drugs within needles due to the drug diffusion from needles to base during the micromolding process, which may lead to imprecise dose and limited drug delivery efficiency 82 . To deal with this issue, Prausnitz's group 83 , 84 concentrated drugs in tips by incorporating an air bubble at the base of the MNs, which effectively prevented drug diffusion. The multilayered dissolving MNs are also useful to achieve controlled drug delivery 85 , 86 , 87 . Li et al. 88 developed a multilayered MNs patch containing an effervescent backing to facilitate rapid separation. Our group 85 also developed a rapidly separating dissolving MNs to realize precise drug delivery as well as rapid separation property. In this approach, the drugs were concentrated in the needle tip, while the blank separating part allowed rapid separation within 30 s in mimic skin 85 . The materials used as matrix for dissolving MNs should be concerned, which may affect the preparation process and the efficacy of the drug. Moreover, it should be noted that long-term use of dissolving MNs may lead to safety problems of polymer accumulation in the skin 89 . 2.5. Hydrogel-forming MNs Hydrogel-forming MNs are usually fabricated from crosslinked polymeric materials, which can pierce the stratum corneum and absorb interstitial fluid to cause the polymeric matrix swell. The drug diffusion through the swollen matrix allows for the delivery to the dermal tissue. Hydrogel-forming MNs can be removed from the skin, leaving almost no polymeric residue behind 22 . Besides, the hydrogel-forming MNs also involve a one-step application, and its drug diffusion will not be blocked by compressed skin tissue like hollow MNs 22 . Hydrogel-forming MNs usually does not contain the drug, and instead, drugs are loaded into a matching reservoir, such as a polymeric film 90 . Therefore, it is not limited by the amount of drug that can be loaded into the needle or needle surface, which significantly increases the drug amount that can permeate into the skin. Recently, other forms of hydrogel-forming MNs have also appeared, in which the drug has not been loaded separately from the needles 73 , 91 . Novel in situ hydrogel-forming MNs were also developed using biocompatible thermosensitive copolymer. Sivaraman et al. 92 utilized the transition property of poloxamer from solution at room temperature to gel at skin temperature (32 °C) to prepare in situ hydrogel-forming MNs. No matter where the drug is located, the swelling degree of the hydrogel matrix plays a key role in drug delivery, and altering the crosslink density of the matrix can control release rate 93 . Hydrogel-forming MNs can also be used for diagnostic purpose through the analysis of interstitial fluid absorbed by the MNs upon insertion into the skin 94 . Hydrogel-forming MNs are fabricated by swellable materials formed by chemically or physically cross-linking polymers 95 , such as crosslinked poly (methylvinylether/maleic acid) (PMVE/MA)-poly(ethylene glycol) (PEG) 10,000 96 , and PVA-dextran 73 . Hydrogel-forming MNs can be regarded as a subtype of polymeric MNs where the polymers display physicochemical properties of the hydrogel 97 . Typically, micromolding method is widely employed to prepare hydrogel-forming MNs. According to the research conducted by Donnelly et al. 96 , an aqueous blend containing PMVE/MA and PEG10,000 was used to produce hydrogel-forming MNs by using silicone micromold. The adhesive drug reservoir patch was prepared in advance and then attached to the needles with moderate pressure, thereby forming an integrated hydrogel MNs system. This system successfully delivered various drugs with different molecular weights, including large molecular weight proteins and peptides (insulin and BSA) 96 . Yang et al. 73 designed a phase-transition MNs system which enabled highly efficient transdermal delivery of insulin by utilizing polyvinyl alcohol as the microneedle material via microcrystalline cross-linking strategy. Lutton et al. 98 also designed a scalable manufacturing process for hydrogel-forming MNs, which was conducted at ambient condition utilizing a combination of injection moulding and roller casting. Since the hydrogel-forming MNs are commonly fabricated from polymeric materials, it should be noted that their mechanical strength and physical stability are possible concerns during the application and storage process. 3. Application of MNs-mediated protein and peptide delivery Proteins and peptides have become significant therapeutic modalities for various diseases, which continue to enter the market at a steady pace 99 , 100 , 101 . This can be attributed to their target specificity, high potency, and favorable safety compared with traditional small-molecule drugs. As a minimally invasive device, MNs can improve the patient's compliance and offer a multifunctional platform to overcome the skin barrier for hydrophilic and macromolecular drugs 32 . Moreover, the mild fabrication condition and solid state nature are a major advantage of MNs compared to traditional injection of the aqueous solution, which can improve drug stability and reduce the use of cold chain 80 . With the progress of material science and microfabrication technology, many MNs-mediated protein and peptide delivery strategies have been developed. Typically, MNs have been utilized to deliver various forms of cargoes, from native drugs to the nanoparticle or microparticle-based formulations 27 . In this section, we summarized the recent advances in MNs-mediated protein and peptide delivery, especially focused on their application for infectious disease therapy, diabetes therapy, and cancer therapy. 3.1. Infectious disease therapy Infectious diseases such as influenza, measles, and hepatitis B are one of the main causes of human deaths, which is a major public health concern worldwide. Vaccination has been recognized as the most successful, and cost-effective public health intervention strategy to combat infectious diseases 47 , 102 . Compared with other antigen molecules, only proteins can induce both cellular and humoral immunity 103 . In addition, the versatility and customizability of proteins make protein-based vaccines one of the most effective strategies for artificially immunity induction 103 . Most vaccines are administered by subcutaneous or intramuscular injection, which is relatively painful, resulting in poor patient compliance 104 . There are a large number of antigen presenting cell populations in the skin, such as macrophages, dermal dendritic cells (DCs), and Langerhans cells, making the skin a unique target for immunomodulation 59 , 105 , 106 , 107 . MNs are easy to use with minimal pain, which provide a promising platform for transcutaneous immunization with improved efficacy 108 , 109 , 110 ( Fig. 3 ). Over the past few decades, MNs have been developed successfully as an experimental delivery system for various protein and peptide vaccines ( Table 1 ). Figure 3 Mechanisms of MNs-mediated transdermal immunomodulation. Figure 3 Table 1 MNs-mediated transdermal delivery of proteins and peptides for prophylaxis of infectious diseases. Table 1 Disease Protein/peptide drug MNs type MNs material Ref. Model OVA Hollow MNs Silica 111 , 112 OVA Coated MNs Titanium 37 , 113 OVA Coated MNs PLLA 114 OVA Coated MNs PLGA 115 OVA Coated and hydrogel-forming MNs Zein 116 OVA Dissolving MNs PMVE/MA 117 , 118 OVA and platycodin Dissolving MNs HA 119 OVA and Poly(I:C) Dissolving MNs CMC, trehalose 120 , 121 OVA and Poly(I:C) Dissolving MNs PLGA and poly(acrylic acid) 122 OVA and Poly(I:C) Dissolving MNs Silk and poly(acrylic acid) 123 OVA Dissolving and hydrogel-forming MNs PMVE/MA, PEG, sodium carbonate/Gantrez S-97 124 BSA and recombinant protective antigen MicroCor™ (dissolving MNs) PVA, trehalose, maltitol, HP- β -CD 125 Influenza Inactivated influenza virus proteins Coated MNs Stainless steel 126 Adenoviral serotype Coated MNs PLA 127 Envelope protein Domain III subunit antigen Coated MNs Poly( l -lactic acid) 128 Virus vaccine antigens Dissolving MNs PVP 72 Virus vaccine antigens Dissolving MNs Trehalose and sodium CMC 129 Influenza antigens Dissolving MNs Trehalose/sucrose, sucrose/arginine, and arginine/heptagluconate 130 Hemagglutinin Dissolving MNs CMC sodium, ammonium acetate buffer, PVA, sucrose 131 4M2e-tFliC fusion protein Dissolving MNs CMC sodium, arginine/heptagluconate, sucrose 132 Influenza subunit vaccine and GM-CSF Dissolving MNs PVA, BSA, CMC, trehalose 133 HIV Recombinant HIV-1 CN54gp140 Dissolving MNs Gantrez® AN-139 134 Trimer immunogen and adjuvant Dissolving MNs Poly(acrylic acid) and silk 135 Pneumonia Recombinant protein subunit Dissolving MNs CMC 136 Diarrhea Rotavirus vaccine Coated MNs Stainless steel 137 Hepatitis B Surface antigen Coated MNs Titanium 138 Plague F1 antigen Microchannel Skin System Plastic 139 Tuberculosis Protein derivative Dissolving MNs HA 140 Measles 1000 TCID50 Dissolving MNs Sucrose, threonine, and CMC 141 Leishmaniasis Recombinant protein LiHyp1 Dissolving MNs Sugar 142 The MNs-mediated transcutaneous vaccination can effectively present antigens to skin-resident immunocyte which often enables lower dose and stronger topical immunization 143 , 144 . Matriano et al. 37 compared different routes of OVA (model antigen) administration, and when the protein antigen was delivered, the immune response was most efficient by using coated MNs and intradermal administration as compared to subcutaneous or intramuscular administration. Similarly, the titers of IgG in mice that received 0.5 μg of antigen with MNs were comparable or higher than those received 5 μg of antigen by intramuscular administration 137 . Dissolving MNs for influenza vaccine delivery could also improve the efficiency of virus clearance and enhance cellular recall response, compared with conventional intramuscular injection 72 , 129 . The key parameter of protein and peptide vaccine formulation is to maintain the stability of the vaccine component, which is crucial during the fabrication, transportation, and storage process. Appropriate formulation techniques using MNs can retain the long-term antigen immunogenicity and allow flexible storage conditions 145 , 146 . DeMuth et al. 127 found that the sucrose-coated MNs effectively delivered adenovirus into the skin and allowed storage at room temperature for several months without losing the biological activity of adenovirus vectors. Mistilis et al. 130 screened different dissolving MNs formulation combinations to stabilize a trivalent subunit influenza vaccine. After being stored at 25 °C for 24 months, dissolving MNs formulated by combinations of arginine/heptagluconate, sucrose/arginine, and trehalose/sucrose still retained the vaccine immunogenicity. The mice immunization experiment also proved that the antibody titer was equivalent to the fresh liquid vaccine provided by intradermal injection 130 . Many available vaccines are formulated with adjuvant 112 , 119 , 121 , 122 , 123 . Balmert et al. 121 used dissolving MNs to deliver OVA and Poly(I:C) adjuvant. Although the addition of Poly(I:C) showed little effect on the IgG1 response, it promoted a moderate increase in IgG2c response. Specifically, many MNs polymeric matrix materials can also be adapted as adjuvants to enhance the immune response ascribed to their intrinsic immunogenicity. For example, poly[di(carboxylatophenoxy)phosphazene] can serve as both vaccine adjuvant and fabrication material. When used in coated MNs for antigen delivery, it exhibited superior activity in pigs and significant antigen sparing potential compared to intramuscular administration 138 . It can be predicted that this will further promote the application of polymeric MNs in immunity. OVA, a model protein with unique lymph node-targeting ability, is commonly used to assess the performance of MNs for immunization 37 , 111 , 112 , 113 , 114 , 115 , 116 , 117 , 118 , 119 , 121 , 124 . Zaric et al. 118 encapsulated OVA into PLGA nanoparticles which were then delivered to the skin by the dissolving MNs. Skin-derived DCs could deliver nanoparticles to skin draining lymph nodes through afferent lymphatic vessels, thereby inducing a potent antigen-specific immune response. Besides, PLGA nanoencapsulation maintained the stability of antigen in the dissolving MNs which further facilitated antigen retention into the skin 118 . He et al. 114 prepared a layer-by-layer coated MNs based on a synthetic pH-induced charge-invertible polymer to shorten the implantation time, which only required 60 s to implant layer by layer films in vivo during the insertion process ( Fig. 4 ). The coated MNs triggered a strong immune response, and the serum OVA-specific IgG1 levels of the coated MNs group were 160 times and 9 times higher than that of the subcutaneous and intramuscular injection groups, respectively 114 . Figure 4 The implantation of layer-by-layer drug films using coated MNs for enhanced transdermal vaccination. Reprinted with permission from Ref.  114 . Copyright © 2018, American Chemical Society. Figure 4 With the rapid development of nanotechnology, recently the MNs have been employed to efficiently deliver macromolecules along with nanoparticle-based therapies. The advantages of both nanoparticles and MNs can be leveraged to improve the transdermal delivery efficiency of proteins and peptides. Du et al. 112 compared intradermal delivery efficiency of four nanoparticulate vaccines using hollow MNs. Although both nanoparticles and solution aroused strong total IgG and IgG1 responses, the nanoparticles significantly increased the IgG2a response 112 . MNs-mediated transdermal immunomodulation has been mostly studied for influenza 72 , 126 , 127 , 128 , 129 , 130 , 131 , 132 , 133 . Zhu et al. 126 coated virus protein on stainless MNs and then used them to immunize mice. Four weeks after immunization, all mice immunized with virus-coated MNs survived as well as intramuscular injection, while the mice in the control group died on Day 5–8 after challenge 126 . Littauer et al. 133 demonstrated that incorporation of the thermolabile granulocyte-macrophage colony stimulating factor into the H1N1 vaccine-loaded dissolving MNs could result in improved vaccine-induced immunity, which provides a pipeline to other active recombinant molecules as adjuvants for maximized vaccination efficacy to combat with influenza. MNs-mediated transdermal immunomodulation has also been widely investigated to combat other infectious diseases, such as HIV 134 , 135 , diarrhea 137 , hepatitis B 138 , plague 139 , tuberculosis 140 , measles 141 , and leishmaniasis 142 , with representative examples listed in Table 1 . Especially, the recent prevalent COVID-19 coronaviruses have caused a serious threat to public health. Coronaviruses-S1 subunit vaccines are a promising immunization modality against coronaviruses infection. Kim et al. 136 , 147 incorporated the protein into carboxymethyl cellulose to fabricate the dissolving MNs at room temperature. All dissolving MNs vaccines elicited higher levels of neutralizing antibody, even beyond those induced by subcutaneous injection of monophosphoryl lipid A adjuvanted vaccine. Although its efficacy and safety need further research, transdermal delivery of proteins and peptides based on MNs represents a promising strategy for combating various infectious diseases. In particular, for vaccines that require multiple administrations, transdermal MNs vaccination provides a much more convenient option. 3.2. Diabetes therapy Diabetes is a chronic disease of glucose metabolism disorder characterized by abnormal accumulation of glucose in the blood 148 . Diabetes is commonly induced by the reduced insulin secretion (type 1) or the defective responsiveness of the body to insulin (type 2) 149 , 150 . Exogenous insulin administration is indispensable for the treatment of diabetes 151 , 152 . Insulin, a 51-amino-acid peptide, is one of the hormones for modulating blood glucose level. However, the great pain caused by frequent and repeated subcutaneous injections adversely affects compliance with treatment 153 . In contrast, transdermal delivery of insulin is an attractive delivery method 105 , 154 . Introducing MNs into insulin delivery will benefit a large number of diabetic patients because it is minimal pain and easy to administer 26 , 155 , 156 . The solid MNs fabricated by different materials, such as silicon 157 , metal 158 , and polymer 44 , have successfully reduced the blood glucose level by improving the insulin permeability through skin pretreatment. Zhou et al. 158 used stainless steel MNs with different needle lengths to evaluate the delivery efficacy of insulin to diabetic rats. The results showed that the skin's permeability to insulin increased, and blood glucose levels decreased rapidly within 1 h 158 . Besides, the integration of solid MNs with other techniques such as iontophoresis can further enhance the transdermal delivery efficiency of insulin 159 , 160 . Hollow MNs-mediated intradermal insulin delivery results in faster insulin onset, which can be driven by passive diffusion 161 , pressure 44 , or electricity 162 . McAllister et al. 44 found that hollow MNs allowed microliter of solutions to enter the skin, and a larger pressure triggered a faster decrease in blood glucose levels. Roxhed et al. 162 designed a patch system based on MNs with an electronically controlled liquid dispenser. The plasma insulin concentration of the electrically driven active administration was about 5 times higher than that of the passive diffusion group at 3 h post dosing 162 . Insulin delivery using drug-free MNs (solid MNs, hollow MNs) generally requires two or more steps, which is inconvenient for patients. The drug-loaded MNs (coated MNs, dissolving MNs, hydrogel-forming MNs) can overcome these issues 26 . Ross et al. 163 developed insulin polymeric layers coated metal MNs. The thin and homogeneous layers could retain insulin intact, and rapid insulin release was realized within 20 min, indicating that solid-state insulin delivery by coated MNs is feasible. However, further studies about insulin coated MNs are limited, which probably due to the insufficient dose of coated insulin. Dissolving MNs encapsulated insulin in the MNs matrix are more promising due to their favorable biocompatibility, relatively simple manufacturing method, and low cost 22 . Since insulin is heat-sensitive, it is important to incorporate insulin in dissolving MNs at mild temperature. Various water-soluble polymers such as HA 164 , chondroitin sulfate 12 , poly-gamma-glutamic acid 165 , and a mixture of starch and gelatin 166 had been employed to prepare insulin loaded dissolving MNs at room temperature by using micromold casting method. Liu et al. 164 evaluated the ability of dissolving MNs prepared by HA to deliver insulin to diabetic rats in vivo . The results showed that insulin administered through dissolving MNs could effectively enter the systemic circulation, and the hypoglycemic effect was almost similar to subcutaneous injection 164 . Conventional diabetes treatment based on subcutaneous injection is usually associated with poor blood glucose control. The closed-loop drug delivery strategy can delicately control the insulin release profile in response to fluctuations in blood glucose levels, which shows great promise in the diabetes treatment. Hence, glucose-responsive MNs have been developed based on the glucose-sensing elements, such as glucose oxidase (GOx) 167 , 168 , 169 , 170 , 171 , 172 , 173 and phenylboronic acid 174 , 175 . Yu et al. 174 designed an MNs patch loaded with insulin by using a non-degradable glucose-responsive polymer. Under the hyperglycaemic condition, the polymeric matrix swelled and weakened the electrostatic interaction between the negatively charged polymers and insulin, thereby promoting the release of insulin. When exposed to euglycemic condition, the inhibited volume change and the restoration of electrostatic interaction slowed down the insulin release rate 174 . Another potential approach to combat diabetes is using glucagon-like peptide-1 receptor agonists 173 , 176 , 177 . Chen et al. 173 constructed a smart exendin-4 (Ex4), a synthetic 39-amino acid peptide, delivery platform based on MNs incorporated with dual mineralized microparticles separately containing GOx and exendin-4 ( Fig. 5 ). The closed-loop MNs system showed excellent glucose regulation ability by the rapid specific response to hyperglycemia state, thereby significantly improving the therapeutic performance of exendin-4 173 . Figure 5 The MNs patch incorporated with dual mineralized microparticles for diabetes therapy. (A) Schematic of glucose-responsive Ex4 delivery mediated by MNs patch. (B) Photograph of the mouse after inserted by an MNs patch. Scale bar, 500 μm. (C) Long-term blood glucose level of mice after different treatments (mean ± SD, n  = 3). (D) The area under the curve of blood glucose level (mean ± SD, n  = 3). Reprinted with permission from Ref.  173 . Copyright © 2017, Springer Nature. Figure 5 3.3. Cancer therapy Cancer is the main concern of public health due to the widespread prevalence, high morbidity and mortality 178 . Apart from surgery, radiotherapy, and chemotherapy, immunotherapy has become an effective strategy for cancer treatment. Instead of directly killing the tumor cells, immunotherapeutic drugs are utilized to activate the body's immune system to attack the cancer cells, many of which are evaded when cancer occurs 179 . Therefore, immunotherapy is considered a promising strategy to treat or even cure certain types of cancer. The number of approved immunotherapeutic drugs has been increasing, and there are many treatments in preclinical and clinical stages. Generally, immunotherapeutic agents are mainly divided into five categories: cancer vaccines, checkpoint inhibitors, engineered T cells, lymphocyte-promoting cytokines, agonistic antibodies against co-stimulatory receptors 180 , many of which are composed of proteins and peptides. In the preclinical studies, many MNs-mediated transdermal deliveries of proteins and peptides have shown promising efficacy in cancer immunotherapy ( Table 2 ). Table 2 MNs-mediated transdermal delivery of proteins and peptides for cancer immunotherapy. Table 2 Therapy Protein/peptide drug MNs type MNs material Ref. Cancer vaccine OVA Dissolving MNs PMVE/MA 118 OVA and resiquimod (R848) Dissolving MNs Pluronic F127/PEG 181 Human melanoma antigens (Trp2) and adjuvant (CpG) Coated MNs PLLA 182 Microparticulate ovarian cancer vaccine AdminPen™ (Hollow MNs) Stainless steel 183 Whole cell lysate of B16F10 cancer cells, GM-CSF Dissolving MNs HA 184 Murine breast cancer whole cell lysate Solid MNs Metal 185 S-91 melanoma cancer cells vaccine antigen Solid MNs Dermaroller 186 HPV E743–63 synthetic long peptide Hollow MNs Silica capillaries 63 Gene therapy Octaarginine/BRAF siRNA Coated MNs Stainless steel 187 Plasmid OVA and poly(I:C) Dissolving MNs A cationic polypeptide and PEG 188 Checkpoint inhibitors aPD-1 Dissolving MNs HA 189 aPD-1 Hollow MNs PVP/PVA 190 aCTLA-4 Dissolving MNs PVP 191 aPD-1 and 1-methyl- d , l -tryptophan Dissolving MNs HA 192 aCTLA-4 and zinc phthalocyanine Dissolving MNs HA 193 1-Methyl- d , l -tryptophan and ICG Dissolving MNs HA, PVP, PVA 194 aPD-1: anti-programmed cell death protein 1 antibodies; aPD-L1: anti-programmed death-ligand 1 antibodies; aCTLA-4: anti-cytotoxic T-lymphocyte-associated protein 4 antibodies; ICG: indocyanine green. Therapeutic cancer vaccines represent a viable option for active immunotherapy of cancers by using a patient's own immune system, which include cell vaccines (tumor or immune cell), genetic (DNA, RNA, and viral) vaccines, and protein/peptide-based vaccines 195 . Vaccination with antigens by MNs can generate a robust antigen-specific cellular immune response. By activating antigen-specific CD8 cytotoxic T-lymphocytes, it can effectively eliminate tumors, just like the complete vaccination protection of the body in infectious diseases 118 . The immune adjuvant can be used simultaneously with the antigen or in advance, which can non-specifically enhance the body's immune response to the antigen. Kim et al. 181 utilized dissolving MNs to deliver model antigen (OVA) and immunostimulatory adjuvant (resiquimod) into lymph nodes to mature and activate antigen-presenting cells ( Fig. 6 ). The dissolving MNs based on amphiphilic triblock copolymer could generate nanomicelles in situ after being dissolved in the skin, which facilitated the delivery of poorly water-soluble resiquimod. The results of antitumor immune response showed that the application of the dissolving MNs containing OVA and resiquimod to tumor-bearing mice induced a significant level of antigen-specific cellular and humoral immunity 181 . Figure 6 Enhanced cancer vaccination by in situ nanomicelle-generating dissolving MNs containing OVA and resiquimod (R848). Reprinted with permission from Ref.  181 . Copyright © 2018, American Chemical Society. Figure 6 Proteins and peptides with catalytic abilities can be used as adjuvant agents for other therapeutic modalities or as anticancer drugs themselves 196 . Meanwhile, certain proteins and peptides can also work as drug delivery carriers, due to their biocompatibility and bioresorbable ability. Some cell-penetrating peptides can be combined with vaccines for immunotherapy. Ruan et al. 187 developed an siBraf delivery system based on cell-penetrating peptide octaarginine nanocomplexes combined with coated MNs for targeted anti-melanoma treatment. The results showed that octaarginine presented lower cytotoxicity than polyethyleneimine, while exhibited comparable gene transfection and silencing efficacy. The octaarginine/siBraf coated MNs could successfully pierce into the melanoma site and effectively inhibit tumor growth 187 . Duong et al. 188 developed a dissolving MNs-based polypeptide cocktail to augment cancer immunotherapy. Compared with subcutaneous vaccination, the dissolving MNs induced higher OVA-specific antibody titer and significantly inhibited OVA-expressing metastatic tumor. The immunomodulatory antibodies can induce a powerful antitumor immune response. However, they usually generate substantial autoimmunity, leading to adverse effects 197 . Targeted and controlled release of antibodies in the desired cell types can achieve minimal off-target effects and reduce toxicity. MNs can directly accumulate sufficient immunotherapies within the topical disease site to effectively target the desired tumor and immune cells. Therefore, integrating MNs with immunomodulatory antibody is promising for fighting against malignant tumors. In particular, nanoparticles-encapsulated MNs have been designed to enable controlled release of immune checkpoint inhibitors, including aPD-1/aPD-L1 189,190 , aCTLA-4 191,194 , and 1-methyl-D,L-tryptophan 192 , 194 . Wang et al. 189 developed a self-degradable MNs for the sustained delivery of aPD-1. Hyaluronic acid integrated with pH-sensitive dextran nanoparticles containing aPD-1 and GOx were formulated into MNs. The tumor acidic microenvironment promoted the sustained release of aPD-1. In vivo antitumor study in mice melanoma model showed that application of the self-degradable MNs induced strong immune response compared to the MNs without degradation trigger or intratumor injection of free aPD-1 189 . The MNs co-loaded with different checkpoint inhibitors resulted in the synergistic treatment of tumors 189 , 192 . Ye et al. 192 constructed the MNs platform to co-deliver aPD-1 and 1-methyl-D,L-tryptophan. The results demonstrated that the synergistic treatment enhanced effective T cell immunity in a B16F10 melanoma model 192 . Drug delivery based on MNs usually relies on passive diffusion, which may limit the distribution and penetration depth of the therapeutic agents. Lopez-Ramirez et al. 191 loaded magnesium particles into the MNs as a built-in engine to achieve faster and deeper intradermal drug delivery ( Fig. 7 ). The magnesium particles could react with the interstitial fluid to quickly generate H 2 bubbles, thereby providing extremely local high fluid flow to break through the dermal barrier and enhance local payload delivery 191 . In vivo antitumor experiments showed that the passive MNs delivering the therapeutic aCTLA-4 initially delayed tumor growth of B16F10 melanoma. However, by day 46, all mice in this group showed exceeding tumor burden of 1500 mm 3 . In sharp contrast, 60% of the mice treated with the active MNs exhibited a completely tumor-free state 191 . Figure 7 Built-in active MNs patch with enhanced drug delivery. (A) Schematic illustration of the design and mechanism of the active MNs patch. (B) Drug release kinetics of different MNs at pH 6.0. (C) Corresponding release percentage of aCTLA-4. (D) The fluorescence images of MNs patch obtained from top view. (i) Blank MNs, (ii) FITC-loaded MNs, and (iii) FITC-loaded active MNs. Scale bar, 1 mm. Reprinted with permission from Ref.  191 . Copyright © 2019, John Wiley and Sons. Figure 7 Immune checkpoint blockade therapy based on MNs can be combined with other cancer therapies. Besides, the activation of the skin immune system can enhance anti-cancer immunity both locally and systemically 190 , 194 . Chen et al. 190 developed hollow MNs that combined checkpoint inhibitor and cold atmospheric plasma. Cold atmospheric plasma induced tumor cell death, and the released tumor-associated antigens then initiated immune response. Meanwhile, aPD-L1 released from the hollow MNs patch further augmented the antitumor immunity. Immunotherapy combined with phototherapy is also used to further enhance the anti-cancer effect 190 . Chen et al. 193 designed a MNs-assisted platform for synergistic photodynamic and immunotherapy, which simultaneously encapsulated hydrophobic zinc phthalocyanine and hydrophilic aCTLA-4. In this approach, photodynamic therapy worked firstly to kill tumor and triggered the immune response, subsequently facilitated robust immunotherapy with aCTLA-4 193 . Our group 194 also designed a core‒shell structure MNs to boost the immune response by combining photothermal therapy and immunotherapy. The obtained system could effectively eradicate primary melanoma tumor and inhibit metastasized tumor 194 . In addition to immunotherapy, proteins can also exert an anti-cancer effect through other therapies. For example, bevacizumab can be used to treat a variety of cancers by inhibiting tumor angiogenesis. Courtenay et al. 198 provided high dose transdermal delivery of bevacizumab using MNs, which highlighted the potential of MNs to provide sustained drug delivery to the systemic and lymph circulation. Collectively, the delivery of proteins and peptides assisted by MNs for cancer treatment is a useful strategy. 3.4. Other disease therapy MNs-mediated transdermal protein and peptide delivery can also be used in other disease therapy, such as hypoglycemia 199 , osteoporosis 200 , cosmeceuticals 45 , and wound healing 201 . The administration of insulin may cause hypoglycemia, a life-threatening condition characterized by abnormally low blood glucose level 202 . To address this issue, GhavamiNejad et al. 199 designed a smart MNs patch to specifically release glucagon at the hypoglycemia condition. The MNs patch was prepared by a photo-crosslinked methacrylated hyaluronic acid embedded multifunctional microgels, which enabled hypoglycemia triggered release property ( Fig. 8 ). In the type 1 diabetes rat model, the MNs patch successfully prevented hypoglycemia caused by insulin overdose 199 . Figure 8 Schematic illustration of the controlled glucagon release from the MNs patch. (A) The fabrication process of MNs patch. (B) The mechanism of glucagon release from the MNs patch. Reprinted with permission from Ref.  199 . Copyright © 2019, John Wiley and Sons. Figure 8 Naito et al. 200 designed a dissolving MNs patch loaded with human parathyroid hormone to treat osteoporosis. The MNs obviously improved the stability of parathyroid hormone compared to solution. The in vivo study showed that the bioavailability of parathyroid hormone-loaded MNs was 100 ± 4% relative to subcutaneous injection. In a rat model of osteoporosis, parathyroid hormone-loaded MNs successfully inhibited the decrease in bone density. Proteins and peptides play an important role in cosmetic applications. Mohammed et al. 45 investigated the effect of stainless steel MNs on the skin penetration of different chain length peptides, including melanostatin, rigin, and palmitoyl-pentapeptide. They observed that peptides with smaller molecular weight were associated with local delivery enhancement 45 . Chi et al. 201 developed vascular endothelial growth factor encapsulated chitosan MNs to promote wound healing. The drug release could be controlled via the temperature rise induced by the inflammation response at the wound site. The in vitro antibacterial test and in vivo wound healing study suggested that the MNs patch could promote collagen deposition, inflammatory inhibition, and tissue regeneration during wound closure 201 . 4. MNs-mediated protein and peptide delivery in the clinic As mentioned above, the fundamental research has proved the advantages and feasibility of MNs-mediated protein and peptide delivery. At present, many therapies based on MNs-mediated transdermal delivery of protein and peptide drugs have entered clinical use. As shown in Table 3 , most currently active clinical trials focus on the vaccination of infectious diseases and insulin delivery for diabetes treatment. These clinical trials mainly utilized the hollow MNs infusion system, and a few investigated dissolving or coated MNs. This is mainly because the research on coated MNs, dissolving MNs or hydrogel-forming MNs started later. And they usually require more sophisticated MNs design and manufacturing techniques. The interdisciplinary divide between microfabrication and pharmaceutical research also delayed the development of drug delivery 23 . At this stage, the field is at an important transitional point. More MNs products will be translated into clinical and medical practice in the near future. Table 3 Currently active clinical trials with MNs for therapeutic protein and peptide delivery. Table 3 Condition or disease Therapeutic agent MNs type CT phase NCT identifier Influenza Inactivated influenza vaccine (IIV) Dissolving MNs 1 NCT02438423 Influenza Trivalent influenza vaccine Hollow MNs 1/2 NCT01707602 Influenza Intanza ® A micro-needle injection system 4 NCT01368796 Influenza S-OIV H1N1 vaccine MicronJet 600 (hollow MNs) Not applicable NCT01049490 Influenza Influenza vaccine (TIV 2010/2011) Microneedle device (hollow MNs) Not applicable NCT01304563 Influenza Flu vaccine Microneedle injectors (hollow MNs) Not applicable NCT00558649 Healthy H1N1 pandemic influenza Microneedle device Not applicable NCT01039623 Measles and Rubella Measles rubella vaccine Dissolving MNs 1/2 NCT04394689 Renal Failure HBV vaccine A novel intradermal microneedle 2/3 NCT02621112 Varicella Zoster infection Zostavax A novel intradermal microneedle 2/3 NCT02329457 Atopic dermatitis Fluzone® intradermal An ultra-fine micro-needle 1 NCT01518478 Atopic dermatitis Fluzone® intradermal An ultra-fine micro-needle Not applicable NCT01737710 Intradermal injections Insulin MicronJet (hollow MNs) 1 NCT00602914 Diabetes Insulin Hollow MNs 1/2 NCT01061216 Diabetes Insulin Hollow MNs 2/3 NCT00837512 Diabetes C19-A3 GNP peptide Nanopass microneedles 1 NCT02837094 Diabetes Insulin and glucagon MicronJet (hollow MNs) 2 NCT01684956 Hypoglycemia Glucagon Microneedle patch system 1 NCT02459938 Postmenopausal osteoporosis Abaloparatide Solid microstructured transdermal system 3 NCT04064411 Postmenopausal osteoporosis Abaloparatide Coated transdermal microarray 2 NCT01674621 Postmenopausal osteoporosis Zosano Pharma parathyroid hormone Coated MNs 1 NCT02478879 Primary axillary hyperhidrosis Botulinum toxin type A Fractional micro-needle radiofrequency Not applicable NCT03054480 Poliomyelitis Fractional IPV MicronJet600 (hollow MNs) 3 NCT01813604 Auto-immune/auto-inflammatory diseases Adalimumab MicronJet600 (hollow MNs) 1/2 NCT03607903 5. Conclusions and prospects Proteins and peptides have high specificity and potency compared to small molecules, which have been demonstrated to be effective for the treatment of various diseases. Nonetheless, because of the inherent properties of proteins and peptides, such as large molecular weight, poor stability, and conformational flexibility, they are usually administered by injection, which is inconvenient and unfriendly. MNs can improve the patient's compliance and overcome the skin barrier for protein and peptide drugs. MNs have been developed in several designs with different delivery strategies, which can be generally classified into solid MNs, coated MNs, hollow MNs, dissolving MNs, and hydrogel-forming MNs. Skin plays a unique role in biology and immunomodulation. The active immune environment in the skin can synergize with the MNs-mediated vaccine delivery to fight infectious diseases and treat cancers. It is also an important application for MNs in diabetes treatment, and MNs also make safer closed-loop glucose-responsive therapies possible. MNs-mediated transdermal delivery of checkpoint inhibitors has reduced their off-target effect and achieved local targeted delivery to treat superficial cancers. In short, MNs are a very promising strategy for protein and peptide delivery to treat various diseases. The successful formulation of proteins and peptides depends on a thorough understanding of their physicochemical and biological characteristics. Notably, the formulation and handling of proteins and peptides need special attention in optimizing their stability and efficacy. The researches for addressing fundamental issues including drug loading, pharmacokinetic and pharmacodynamic profile, safety, and storage of MNs will promote transdermal protein and peptide drug delivery. With the advancement already achieved in the area of microfabrication technologies available in designing MNs, more intelligent MNs systems will gradually emerge. Proteins and peptides are potent active pharmaceutical ingredients, which may break the limit of low drug loading of MNs. The comprehensive characterization methodologies, including both in vitro and in vivo , have been used to evaluate the ability of MNs to deliver drugs safely and effectively into the skin. The approaches currently used in the field will pave way to the development of standardized protocols for MNs evaluation in the future 97 . It is optimistically expected that extensive academic research in combination with the pharmaceutical industry will further accelerate the clinical translation of MNs-mediated transdermal delivery of protein and peptide drugs. Acknowledgments This work was funded by the National Natural Science Foundation (Project No. 81803466, China), Guangdong Macao joint innovation funding project (Project No. 2020A050515009, China), the Research and Development Plan for Key Areas in Guangdong Province (Project No. 2019B020204002, China), and the Foundation of Traditional Chinese Medicine Bureau of Guangdong Province (Project No. 20191057, China). Author contributions Guilan Quan, Xin Pan and Chuanbin Wu conceived the review. Ting Liu wrote the manuscript with assistance of Minglong Chen, Jingtao Fu, Ying Sun and Chao Lu. Minglong Chen, Guilan Quan and Xin Pan revised the manuscript. All of the authors have read and approved the final manuscript. Conflicts of interest The authors have no conflicts of interest to declare. Footnotes Peer review under responsibility of Chinese Pharmaceutical Association and Institute of Materia Medica, Chinese Academy of Medical Sciences. 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# 微针介导的蛋白多肽类药物经皮递送研究进展

**刘婷^a,陈明龙^a,傅金涛^a,孙颖^a,陆超^b,权桂兰^b\*,潘昕^a\*,吴传斌^b**

^a 中山大学药学院,广州 510006,中国 ^b 暨南大学药学院,广州 510632,中国

**\* 通讯作者。** 电话/传真:+86 20 39943427。 电子邮件:xiaoplanet@163.com;panxin2@mail.sysu.edu.cn

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## 摘要

蛋白质和多肽因其高活性和高特异性已成为治疗多种疾病的重要治疗方式。然而,这些药物固有的特性,如大分子量、稳定性差和构象柔性,使其难以制剂化和递送。注射是蛋白多肽类药物临床给药的主要途径,但通常导致患者依从性较差。微针(MNs)作为一种便携、微创的装置,能够克服皮肤屏障,产生可逆的微通道,从而实现大分子的有效渗透。本综述重点介绍了微针介导的蛋白多肽类药物经皮递送的最新进展。重点阐述了代表性微针设计与制造方面的最新发展。我们还总结了微针介导的蛋白多肽经皮递送的应用现状,特别是在感染性疾病、糖尿病、癌症及其他疾病治疗领域的应用。最后,还提供了临床转化现状及对未来发展的展望。

**关键词:** 微针;经皮给药;蛋白质;多肽;感染性疾病;糖尿病;癌症;临床

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## 1. 引言

蛋白质和多肽在人体中发挥着最显著的作用,如分子转运、生物支架、细胞调节和酶催化,在几乎所有医学领域都发挥着重要作用^1,2,3,4^。胰岛素是1982年首个获批的治疗性蛋白质,此后众多蛋白多肽类药物的临床应用取得了显著进展^5,6^。然而,蛋白多肽类药物的应用通常受到某些限制。这些药物的大分子量显著降低了其跨越皮肤和黏膜等生物屏障的渗透能力。此外,在外部条件(湿度和温度)及内源性蛋白酶作用下导致的生物活性损失,给制剂和递送技术带来了很大困难^7^。

目前,注射是蛋白多肽类药物临床给药的主要途径。静脉注射、皮下注射和肌肉注射是递送蛋白多肽类药物最常用的方式^2,8,9,10,11,12^。无论采用何种注射方式,大多数蛋白多肽类药物都容易被体内各种代谢酶降解,导致体内半衰期短,这意味着需要频繁注射。此外,注射治疗不方便且不友好,尤其对于类风湿性关节炎和糖尿病等慢性疾病患者。注射安全性也需考虑,因为给药过程中针头污染可能导致乙型和丙型肝炎等某些传染病的传播。因此,对于蛋白多肽类药物的递送,迫切需要一种替代药物递送系统,能够便捷给药,同时提高治疗效果、患者依从性和安全性。

经皮给药是一种通过皮肤通道递送生物活性剂以实现局部或全身效应的给药方式,具有无创性和可自我给药的特点^13^。适合经皮给药的药物有一些要求,如最大分子量为1000 Da,且由于角质层屏障的存在需要在疏水性和极性之间取得平衡^14^。大多数蛋白多肽类药物具有亲水性和大分子特性,因此无法轻易渗透进入皮肤。在过去几十年中,各种化学和物理方法,如渗透促进剂^15^、微射流^16^、激光^17^、电穿孔^18^、声孔效应^19^和离子导入^20^,已被开发为改善经皮药物渗透的可行策略。但这些技术通常昂贵且使用繁琐,对大分子药物的成功经皮递送效率仍然有限。

近年来,微针(MNs)已成为一种新型药物递送技术,其应用范围已扩展到各个方面,包括小分子化学药物^21,22^、疫苗^23,24^、基因^25^、蛋白质^4,26^和纳米颗粒^27^。特别是,微针为蛋白质和多肽的经皮递送提供了广阔前景^28,29^。微针是一种微创装置,其针体(<1 mm)有序排列在基底上。它们可以通过在皮肤中产生可逆微通道直接穿透角质层。这些微通道可以使药物进入位于皮肤内层的真皮微循环(图1)。与注射相比,微针不会接触深层真皮中的血管和神经,从而提供更好的患者依从性和良好的安全性。此外,微针的温和制备条件不会影响蛋白质和多肽的生物活性。

**图1.** 常规注射和微针递送蛋白质和多肽药物的示意图。

本综述全面介绍了微针介导的蛋白多肽类药物经皮递送的最新进展。重点阐述了代表性微针设计与制造方面的最新发展和进步。此外,我们总结了微针介导的蛋白多肽递送的最新研究,特别关注其在感染性疾病、糖尿病、癌症及其他疾病治疗领域的应用。最后,还提供了临床转化现状及对未来发展的展望。

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## 2. 微针的代表性类型

Gerstel等人于1971年提出了微针的概念,Henry等人^30^于1998年首次报道了利用微针进行体内经皮给药^30,31^。此后,各种类型的微针被成功开发^32^。根据不同的药物递送策略,微针通常可分为五类,包括固体微针、涂层微针、空心微针、可溶微针和水凝胶微针(图2)。每种类型的微针都已被广泛研究用于经皮给药。然而,与惰性小分子相比,蛋白多肽类药物通常对高温、pH值和有机溶剂敏感^33^。为避免其生物活性受损,有必要了解每种类型微针的特性,然后选择合理的微针类型来制剂。本节详细描述了与不同微针介导递送方法相关的典型应用。

**图2.** 用于经皮给药的代表性微针类型。

### 2.1 固体微针

固体微针通常需要两步操作进行药物递送。简言之,首先将固体微针插入皮肤,然后移除以形成临时微通道。随后,将合适的药物剂型(如凝胶、乳膏或软膏)施加到先前形成的微通道上^23,34^。固体微针应通过选择微针材料提供足够的机械强度以实现成功的皮肤预处理^23^。通常,固体微针由硅^35^和金属^36,37^制备。值得注意的是,硅和金属具有良好的固体微针制备性能,但它们可能不适合经皮给药。其不可降解的特性在插入皮肤后可能引起安全问题。相比之下,高分子材料通常具有良好的生物相容性。各种高分子材料,如聚乳酸(PLA)、聚甲基丙烯酸甲酯、聚碳酸酯和羧甲基纤维素(CMC),已被开发用于制备固体微针,作为不可降解金属或硅的替代品^38,39,40^。

固体微针通过皮肤中产生的微通道以被动扩散方式递送药物。因此,用于皮肤预处理的固体微针的长度和密度设计将影响药物渗透^41,42^。此外,药物的特性也会影响递送效率。与传统经皮递送相反,固体微针预处理形成的微通道将增加亲水性化合物的渗透^43^。McAllister等人^44^证明,使用固体硅微针进行皮肤预处理后,牛血清白蛋白(BSA)和胰岛素的渗透增加。药物的分子量也会影响使用固体微针的被动转运^45,46^。Verbaan等人^46^观察到,较大分子量(72 kDa)化合物的转运速率远低于分子量为10 kDa和538 Da的化合物。

固体微针存在一些固有缺陷。包括微针阵列预处理和随后施用药物制剂的两步给药过程被认为不方便,可能导致剂量不精确^47^。由于对患者依从性的负面影响,基于其他微针的药物递送策略现在变得更加普遍。

### 2.2 涂层微针

为避免两步应用过程,将药物涂覆在针体表面以获得涂层微针。涂层微针为经皮给药提供了更方便和可控的方式。当涂层微针插入时,药物涂层将溶解并将活性药物成分沉积到皮肤中,然后可以移除微针^48^。涂层微针通常由金属或硅制备。为避免使用生物相容性较差的材料,高分子涂层微针也已被广泛研究。固体微结构透皮系统(sMTS)由强聚合物制备,在插入皮肤后能保持其结构完整性^49,50,51^。Kapoor等人^51^开发了用于递送肽A的涂层sMTS。将250微克肽A涂覆在包含316根针的贴片上。成功实现了经皮递送,生物利用度与皮下注射相当。此外,当肽A涂覆在sMTS上时,其稳定性显著提高^51^。

多种技术,如喷雾涂层、浸涂和压电喷墨打印,已被应用于微针涂层^52^。喷雾涂层和浸涂是最常见的方法,使用高粘度的水性药物溶液以在微针表面保留更多药物。主要挑战是如何确保足够治疗剂的均匀涂覆。因此,优化涂层工艺和配方组成非常重要。配方中通常需要表面活性剂、增粘剂和多肽稳定剂,以确保药物的涂层稳定性和均匀性^53^。由于大多数生物分子是亲水的,涂层溶液通常是水性的。Zhao等人^54^开发了一种含有三元共溶剂和聚乙烯醇2000的涂层配方,用于亲水性和疏水性多肽的载药,同时保持生物活性。其他方法如逐层技术也有效用于微针涂层。在这种方法中,通过交替浸入含有相反电荷溶质的两种溶液中,将药物分子涂覆到微针上,形成聚电解质多层膜^55^。

尽管涂层微针通常保持机械强度,但其尖端锋利度随载药量增加而降低,这可能影响皮肤穿透能力^56^。因此,涂层微针的载药量受到限制,这意味着高活性的蛋白质和多肽适合此策略,如去氨加压素^56^、人生长激素^57^和干扰素α^58^。

### 2.3 空心微针

空心微针是亚毫米级装置,作用类似于微米级注射器,可以穿透角质层,使液体制剂流入表皮或真皮^59^。在最简单的形式中,使用空心微针的药物递送通过被动扩散实现。由于致密组织中的被动扩散速率相对较低,通过压力驱动流动或扩散已成功实现更快的转运速率^21,47^。因此,与固体微针相比,空心微针可以允许更大剂量的给药,同时提供精确的转运速率^21,60,61,62^。

数字控制的空心微针注射系统(DC-hMN-iSystem)可以提供精确量的治疗性疫苗。小鼠免疫研究表明,通过DC-hMN-iSystem递送的HPV肽疫苗诱导了强大的细胞毒性和T辅助反应^63^。空心微针介导的纳米颗粒皮内递送也是提高疫苗有效性的有效策略。通过空心微针递送的载抗原聚(d,l-乳酸-羟基乙酸)纳米颗粒引发的抗体反应和淋巴细胞数量显著高于肌肉注射和通过空心微针递送的可溶性抗原^64^。

空心微针通常需要更复杂的制备技术。除了制备具有合适内孔的针体外,空心微针还应与某种形式的药物储库结合。空心微针通常由具有不同内孔直径的金属或硅制备,其固有强度低于固体微针,断裂风险更大^65^。

### 2.4 可溶微针

可溶微针通常由可溶性材料制备,治疗剂被整合到针体中,通过针体基质的有效溶解将药物递送到皮肤中^66,67,68^。许多材料已被用于制备可溶微针,从低分子量碳水化合物到高分子可生物降解聚合物,包括葡聚糖、CMC钠、透明质酸(HA)、硫酸软骨素、聚乙烯吡咯烷酮(PVP)和聚乙烯醇(PVA)。使用可溶微针也是一步给药,患者依从性很好。

可溶微针具有独特的优点,即应用后不留有害物质,不产生生物危害性锐器废物^69,70,71^。此外,可溶微针的温和制备条件使其更容易实现工业化,这对蛋白多肽类药物非常有利。包埋生物分子的固态还可以保护其免受冷链储存和运输的影响^72^。

各种方法,如微模塑^73^、绘图光刻^74^、液滴气流吹制^75^、电拉伸^76^和光刻^77^,已被开发用于制备可溶微针。微模塑法应用最广泛。简言之,通过聚合物熔融或溶剂浇铸填充微模具,有时辅以真空和/或离心力。然后使模具固化或使液体在微腔中原位聚合^23^。

应注意,上述方法通常仅适合学术领域微针的小规模制备。对于规模化制备,已设计了几种新技术,以高效、可控和可扩展的方式制造可溶微针^78^。我们课题组还开发了一种基于双穿透阴模的正压微灌注技术^79^,用于可溶微针的规模化制备^79^。

热敏性蛋白质和多肽应在温和条件下包埋于微模具中并固化,以免破坏其活性。Park等人^80^使用微模塑法制备聚乳酸-羟基乙酸共聚物(PLGA)微针,包埋含有BSA和钙黄绿素的微粒。他们证明了使用聚合物微针控制释放钙黄绿素和BSA的可行性^80^。然而,由于加工中使用高温,蛋白质活性有轻微损失。为解决此问题,Lee等人^69^采用更温和的制备条件,由超低粘度CMC制备可溶微针,保持完整的酶活性。类似地,使用线形成聚合物作为基底,在室温下制备了载促红细胞生成素的可溶微针^81^。

尽管可溶微针在经皮给药方面具有显著优点,但由于微模塑过程中药物从针体向基底扩散,难以控制针体内药物的数量和定位,这可能导致剂量不精确和药物递送效率有限^82^。为解决此问题,Prausnitz课题组^83,84^通过在微针基底中引入气泡将药物集中于尖端,有效防止了药物扩散。多层可溶微针也可用于实现可控药物递送^85,86,87^。Li等人^88^开发了一种含有发泡背衬的多层微针贴片,以促进快速分离。我们课题组^85^还开发了一种快速分离的可溶微针,以实现精确的药物递送和快速分离特性。在这种方法中,药物集中于针体尖端,而空白分离部分允许在模拟皮肤中30秒内快速分离^85^。

应关注用作可溶微针基质的材料,这可能影响制备过程和药物疗效。此外,应注意长期使用可溶微针可能导致聚合物在皮肤中积累的安全问题^89^。

### 2.5 水凝胶微针

水凝胶微针通常由交联聚合物材料制备,可以穿透角质层并吸收组织间液导致聚合物基质溶胀。药物通过溶胀基质的扩散允许递送至真皮组织。水凝胶微针可以从皮肤中移除,几乎不留聚合物残留^22^。此外,水凝胶微针也涉及一步给药,其药物扩散不会像空心微针那样被压缩的皮肤组织阻断^22^。

水凝胶微针通常不含药物,药物被装载到匹配的储库中,如聚合物薄膜^90^。因此,它不受可装载到针体或针表面药物量的限制,这显著增加了可渗透到皮肤中的药物量。近年来,也出现了其他形式的水凝胶微针,其中药物未与针体分开装载^73,91^。还使用生物相容性热敏共聚物开发了新型原位水凝胶微针。Sivaraman等人^92^利用泊洛沙姆从室温溶液到皮肤温度(32°C)凝胶的转变特性来制备原位水凝胶微针。

无论药物位于何处,水凝胶基质的溶胀程度在药物递送中起关键作用,改变基质的交联密度可以控制释放速率^93^。水凝胶微针还可用于诊断目的,通过分析微针插入皮肤后吸收的组织间液^94^。

水凝胶微针由通过化学或物理交联聚合物形成的可溶胀材料制备^95^,如交联聚(甲基乙烯基醚/马来酸)(PMVE/MA)-聚乙二醇(PEG)10000^96^和PVA-葡聚糖^73^。水凝胶微针可被视为聚合物微针的一个亚型,其中聚合物表现出水凝胶的物理化学特性^97^。通常,微模塑法被广泛用于制备水凝胶微针。

根据Donnelly等人^96^的研究,使用含有PMVE/MA和PEG10000的水性混合物,通过硅微模具制备水凝胶微针。预先制备粘性药物储库贴片,然后以适度压力连接到针体上,从而形成集成的水凝胶微针系统。该系统成功递送了不同分子量的各种药物,包括大分子量蛋白质和多肽(胰岛素和BSA)^96^。Yang等人^73^设计了一种相变微针系统,通过利用聚乙烯醇作为微针材料,采用微晶交联策略实现了胰岛素的高效经皮递送。Lutton等人^98^还设计了水凝胶微针的可扩展制造工艺,在环境条件下利用注射成型和辊压浇铸的组合进行。

由于水凝胶微针通常由聚合物材料制备,应注意其机械强度和物理稳定性在应用和存储过程中可能是值得关注的问题。

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## 3. 微针介导的蛋白多肽递送的应用

蛋白质和多肽已成为多种疾病的重要治疗方式,并继续以稳定的速度进入市场^99,100,101^。这可归归因于其靶向特异性、高活性以及与传统小分子药物相比良好的安全性。作为一种微创装置,微针可以改善患者依从性,并提供一个多功能平台来克服皮肤屏障,实现亲水性和大分子药物的递送^32^。此外,温和的制备条件和固态性质是微针相比传统水溶液注射的主要优点,可以提高药物稳定性并减少冷链的使用^80^。

随着材料科学和微加工技术的进步,已开发出许多微针介导的蛋白多肽递送策略。通常,微针已被用于递送各种形式的货物,从天然药物到基于纳米颗粒或微粒的制剂^27^。在本节中,我们总结了微针介导的蛋白多肽递送的最新进展,特别关注其在感染性疾病治疗、糖尿病治疗和癌症治疗中的应用。

### 3.1 感染性疾病治疗

流感、麻疹和乙型肝炎等传染病是人类死亡的主要原因之一,是全球主要的公共卫生问题。疫苗接种已被公认为对抗传染病最成功、最具成本效益的公共卫生干预策略^47,102^。与其他抗原分子相比,只有蛋白质能够诱导细胞免疫和体液免疫^103^。此外,蛋白质的多功能性和可定制性使其成为人工免疫诱导最有效的策略之一^103^。

大多数疫苗通过皮下或肌肉注射给药,相对疼痛,导致患者依从性差^104^。皮肤中存在大量抗原呈递细胞群,如巨噬细胞、真皮树突状细胞(DCs)和朗格汉斯细胞,使皮肤成为免疫调节的独特靶点^59,105,106,107^。微针使用简便,疼痛极小,为经皮免疫提供了有前景的平台,可提高疗效^108,109,110^(图3)。在过去几十年中,微针已成功开发为各种蛋白多肽疫苗的实验性递送系统(表1)。

**图3.** 微针介导的经皮免疫调节机制。

**表1.** 微针介导的蛋白质和多肽经皮递送用于感染性疾病预防。

| 疾病 | 蛋白/多肽药物 | 微针类型 | 微针材料 | 参考文献 | |------|-------------|---------|---------|---------| | 模型抗原 | OVA | 空心微针 | 二氧化硅 | 111,112 | | 模型抗原 | OVA | 涂层微针 | 钛 | 37,113 | | 模型抗原 | OVA | 涂层微针 | PLLA | 114 | | 模型抗原 | OVA | 涂层微针 | PLGA | 115 | | 模型抗原 | OVA | 涂层和水凝胶微针 | 玉米醇溶蛋白 | 116 | | 模型抗原 | OVA | 可溶微针 | PMVE/MA | 117,118 | | 模型抗原 | OVA和桔梗皂苷 | 可溶微针 | HA | 119 | | 模型抗原 | OVA和Poly(I:C) | 可溶微针 | CMC、海藻糖 | 120,121 | | 模型抗原 | OVA和Poly(I:C) | 可溶微针 | PLGA和聚丙烯酸 | 122 | | 模型抗原 | OVA和Poly(I:C) | 可溶微针 | 丝素和聚丙烯酸 | 123 | | 模型抗原 | OVA | 可溶和水凝胶微针 | PMVE/MA、PEG、碳酸钠/Gantrez S-97 | 124 | | 模型抗原 | BSA和重组保护性抗原 | MicroCor™(可溶微针) | PVA、海藻糖、麦芽糖醇、HP-β-CD | 125 | | 流感 | 灭活流感病毒蛋白 | 涂层微针 | 不锈钢 | 126 | | 流感 | 腺病毒血清型 | 涂层微针 | PLA | 127 | | 流感 | 包膜蛋白DIII亚单位抗原 | 涂层微针 | 聚(l-乳酸) | 128 | | 流感 | 病毒疫苗抗原 | 可溶微针 | PVP | 72 | | 流感 | 病毒疫苗抗原 | 可溶微针 | 海藻糖和CMC钠 | 129 | | 流感 | 流感抗原 | 可溶微针 | 海藻糖/蔗糖、蔗糖/精氨酸和精氨酸/庚葡萄糖酸盐 | 130 | | 流感 | 血凝素 | 可溶微针 | CMC钠、乙酸铵缓冲液、PVA、蔗糖 | 131 | | 流感 | 4M2e-tFliC融合蛋白 | 可溶微针 | CMC钠、精氨酸/庚葡萄糖酸盐、蔗糖 | 132 | | 流感 | 流感亚单位疫苗和GM-CSF | 可溶微针 | PVA、BSA、CMC、海藻糖 | 133 | | HIV | 重组HIV-1 CN54gp140 | 可溶微针 | Gantrez® AN-139 | 134 | | HIV | 三聚体免疫原和佐剂 | 可溶微针 | 聚丙烯酸和丝素 | 135 | | 肺炎 | 重组蛋白亚单位 | 可溶微针 | CMC | 136 | | 腹泻 | 轮状病毒疫苗 | 涂层微针 | 不锈钢 | 137 | | 乙型肝炎 | 表面抗原 | 涂层微针 | 钛 | 138 | | 鼠疫 | F1抗原 | 微通道皮肤系统 | 塑料 | 139 | | 结核病 | 蛋白衍生物 | 可溶微针 | HA | 140 | | 麻疹 | 1000 TCID50 | 可溶微针 | 蔗糖、苏氨酸和CMC | 141 | | 利什曼病 | 重组蛋白LiHyp1 | 可溶微针 | 糖 | 142 |

微针介导的经皮疫苗接种可以有效地将抗原呈递给皮肤驻留免疫细胞,通常能够实现更低剂量和更强的局部免疫^143,144^。Matriano等人^37^比较了OVA(模型抗原)的不同给药途径,当递送蛋白质抗原时,使用涂层微针和皮内给药的免疫反应比皮下或肌肉注射更有效。类似地,接受0.5 μg抗原微针的小鼠IgG滴度与接受5 μg抗原肌肉注射的小鼠相当或更高^137^。用于流感疫苗递送的可溶微针也可以提高病毒清除效率并增强细胞回忆反应,相比传统肌肉注射^72,129^。

蛋白多肽疫苗配方的关键参数是维持疫苗组分的稳定性,这在制备、运输和储存过程中至关重要。使用微针的适当配方技术可以保留抗原的长期免疫原性并允许灵活的储存条件^145,146^。DeMuth等人^127^发现,蔗糖涂层微针有效地将腺病毒递送到皮肤中,并允许在室温下储存数月而不丧失腺病毒载体的生物活性。Mistilis等人^130^筛选了不同的可溶微针配方组合以稳定三价亚单位流感疫苗。在25°C储存24个月后,由精氨酸/庚葡萄糖酸盐、蔗糖/精氨酸和海藻糖/蔗糖组合配制的可溶微针仍保留了疫苗免疫原性。小鼠免疫实验也证明抗体滴度与皮内注射的新鲜液体疫苗相当^130^。

许多可用疫苗与佐剂一起配制^112,119,121,122,123^。Balmert等人^121^使用可溶微针递送OVA和Poly(I:C)佐剂。尽管添加Poly(I:C)对IgG1反应影响不大,但它促进了IgG2c反应的适度增加。具体而言,许多微针聚合物基质材料也可被改造为佐剂以增强免疫反应,这归因于其内在免疫原性。例如,聚[二(羧基苯氧基)磷腈]既可作为疫苗佐剂又可作为制备材料。当用于涂层微针递送抗原时,与肌肉注射相比,它在猪中表现出优越的活性和显著的抗原节约潜力^138^。可以预测,这将进一步促进聚合物微针在免疫学中的应用。

OVA是一种具有独特淋巴结靶向能力的模型蛋白,通常用于评估微针的免疫性能^37,111,112,113,114,115,116,117,118,119,121,124^。Zaric等人^118^将OVA包封于PLGA纳米颗粒中,然后通过可溶微针递送至皮肤。皮肤来源的DC可以通过传入淋巴管将纳米颗粒递送至皮肤引流淋巴结,从而诱导强效的抗原特异性免疫反应。此外,PLGA纳米包封维持了抗原在可溶微针中的稳定性,进一步促进了抗原在皮肤中的保留^118^。He等人^114^制备了基于合成pH诱导电荷可逆聚合物的逐层涂层微针,以缩短植入时间,在插入过程中仅需60秒即可在体内逐层植入薄膜(图4)。涂层微针引发了强烈的免疫反应,涂层微针组血清OVA特异性IgG1水平分别是皮下和肌肉注射组的160倍和9倍^114^。

**图4.** 使用涂层微针逐层植入药物薄膜以增强经皮疫苗接种。经参考文献^114^许可转载。© 2018,美国化学会。

随着纳米技术的快速发展,最近微针已被用于有效递送大分子以及基于纳米颗粒的治疗。可以利用纳米颗粒和微针两者的优点来提高蛋白质和多肽的经皮递送效率。Du等人^112^比较了使用空心微针的四种纳米颗粒疫苗的皮内递送效率。尽管纳米颗粒和溶液都引发了强烈的总IgG和IgG1反应,但纳米颗粒显著增加了IgG2a反应^112^。

微针介导的经皮免疫调节已被广泛研究用于流感^72,126,127,128,129,130,131,132,133^。Zhu等人^126^在不锈钢微针上涂覆病毒蛋白,然后用于免疫小鼠。免疫四周后,所有病毒涂层微针免疫的小鼠均存活,与肌肉注射一样,而对照组小鼠在攻毒后第5-8天死亡^126^。Littauer等人^133^证明,将热不稳定粒细胞-巨噬细胞集落刺激因子掺入装载H1N1疫苗的可溶微针中可改善疫苗诱导的免疫,这为其他活性重组分子作为佐剂以最大化疫苗接种效果对抗流感提供了途径。

微针介导的经皮免疫调节也被广泛研究用于对抗其他感染性疾病,如HIV^134,135^、腹泻^137^、乙型肝炎^138^、鼠疫^139^、结核病^140^、麻疹^141^和利什曼病^142^,代表性实例列于表1中。特别是,近期流行的新冠病毒对公共卫生造成了严重威胁。冠状病毒S1亚单位疫苗是对抗冠状病毒感染的有前景的免疫方式。Kim等人^136,147^将蛋白质掺入羧甲基纤维素中,在室温下制备可溶微针。所有可溶微针疫苗均诱导了更高水平的中和抗体,甚至超过了注射单磷酰脂质A佐剂疫苗所诱导的水平。尽管其疗效和安全性需要进一步研究,但基于微针的蛋白质和多肽经皮递送代表了一种对抗各种感染性疾病的有前景的策略。特别是,对于需要多次给药的疫苗,经皮微针疫苗接种提供了更方便的选择。

### 3.2 糖尿病治疗

糖尿病是一种以血液中葡萄糖异常积累为特征的慢性葡萄糖代谢紊乱疾病^148^。糖尿病通常由胰岛素分泌减少(1型)或身体对胰岛素的反应缺陷(2型)引起^149,150^。外源性胰岛素给药是糖尿病治疗不可或缺的手段^151,152^。胰岛素是一种51个氨基酸的多肽,是调节血糖水平的激素之一。然而,频繁重复皮下注射带来的巨大疼痛对治疗依从性产生不利影响^153^。相比之下,胰岛素的经皮递送是一种有吸引力的给药方法^105,154^。将微针引入胰岛素递入将使大量糖尿病患者受益,因为它疼痛极小且易于给药^26,155,156^。

由不同材料(如硅^157^、金属^158^和聚合物^44^)制备的固体微针通过改善皮肤预处理后的胰岛素渗透性成功降低了血糖水平。Zhou等人^158^使用不同针体长度的不锈钢微针评估胰岛素向糖尿病大鼠的递送效果。结果表明,皮肤对胰岛素的渗透性增加,血糖水平在1小时内迅速下降^158^。此外,固体微针与其他技术(如离子导入)的整合可以进一步提高胰岛素的经皮递送效率^159,160^。

空心微针介导的皮内胰岛素递送通过被动扩散^161^、压力^44^或电力^162^驱动,导致更快的胰岛素起效。McAllister等人^44^发现空心微针允许微升溶液进入皮肤,更大的压力触发血糖水平更快下降。Roxhed等人^162^设计了一种基于微针的贴片系统,配备电子控制的液体分配器。电驱动主动给药后3小时的血浆胰岛素浓度约为被动扩散组的5倍^162^。

使用无药微针(固体微针、空心微针)递入胰岛素通常需要两步或更多步骤,这对患者来说不方便。载药微针(涂层微针、可溶微针、水凝胶微针)可以克服这些问题^26^。Ross等人^163^开发了胰岛素聚合物层涂覆的金属微针。薄而均匀的层可以保持胰岛素的完整性,在20分钟内实现胰岛素的快速释放,表明通过涂层微针进行固态胰岛素递送是可行的。然而,关于胰岛素涂层微针的进一步研究有限,这可能是由于涂层胰岛素剂量不足。

将胰岛素包封在微针基质中的可溶微针因其良好的生物相容性、相对简单的制造方法和低成本而更有前景^22^。由于胰岛素具有热敏性,在温和温度下将胰岛素掺入可溶微针中非常重要。各种水溶性聚合物,如HA^164^、硫酸软骨素^12^、聚-γ-谷氨酸^165^以及淀粉和明胶的混合物^166^,已被用于在室温下通过微模塑法制备载胰岛素的可溶微针。Liu等人^164^评估了由HA制备的可溶微针向糖尿病大鼠体内递送胰岛素的能力。结果表明,通过可溶微针给药的胰岛素可以有效进入全身循环,降糖效果与皮下注射几乎相似^164^。

基于皮下注射的常规糖尿病治疗通常与血糖控制不佳相关。闭环药物递送策略可以响应血糖水平波动精细控制胰岛素释放曲线,在糖尿病治疗中显示出巨大前景。因此,已基于葡萄糖传感元件开发了葡萄糖响应性微针,如葡萄糖氧化酶(GOx)^167,168,169,170,171,172,173^和苯硼酸^174,175^。

Yu等人^174^使用非降解性葡萄糖响应性聚合物设计了一种装载胰岛素的微针贴片。在高血糖条件下,聚合物基质溶胀并削弱了带负电聚合物与胰岛素之间的静电相互作用,从而促进胰岛素的释放。当暴露于正常血糖条件时,抑制的体积变化和静电相互作用的恢复减慢了胰岛素的释放速率^174^。

对抗糖尿病的另一种潜在方法是使用胰高血糖素样肽-1受体激动剂^173,176,177^。Chen等人^173^构建了一种基于微针的智能艾塞那肽(Ex4,一种合成39个氨基酸的多肽)递送平台,该微针整合了分别含有GOx和艾塞那肽的双重矿化微粒(图5)。闭环微针系统通过快速特异性响应高血糖状态表现出优异的血糖调节能力,从而显著提高了艾塞那肽的治疗效果^173^。

**图5.** 整合双重矿化微粒用于糖尿病治疗的微针贴片。(A)微针贴片介导的葡萄糖响应性Ex4递送示意图。(B)插入微针贴片后小鼠的照片。比例尺,500 μm。(C)不同处理后小鼠的长期血糖水平(平均值±SD,n=3)。(D)血糖水平曲线下面积(平均值±SD,n=3)。经参考文献^173^许可转载。© 2017,Springer Nature。

### 3.3 癌症治疗

由于癌症的广泛流行、高发病率和高死亡率,它已成为公共卫生的主要关注点^178^。除手术、放疗和化疗外,免疫治疗已成为癌症治疗的有效策略。免疫治疗药物不是直接杀死肿瘤细胞,而是用于激活身体的免疫系统攻击癌细胞,其中许多细胞在癌症发生时已被逃逸^179^。因此,免疫治疗被认为是治疗甚至治愈某些类型癌症的有前景的策略。

已批准的免疫治疗药物数量不断增加,许多治疗处于临床前和临床阶段。通常,免疫治疗剂主要分为五类:癌症疫苗、检查点抑制剂、工程化T细胞、淋巴细胞促进细胞因子、针对共刺激受体的激动性抗体^180^,其中许多由蛋白质和多肽组成。

在临床前研究中,许多微针介导的蛋白质和多肽经皮递送在癌症免疫治疗中显示出有前景的疗效(表2)。

**表2.** 微针介导的蛋白质和多肽经皮递送用于癌症免疫治疗。

| 治疗方式 | 蛋白/多肽药物 | 微针类型 | 微针材料 | 参考文献 | |---------|-------------|---------|---------|---------| | 癌症疫苗 | OVA | 可溶微针 | PMVE/MA | 118 | | 癌症疫苗 | OVA和瑞喹莫德(R848) | 可溶微针 | Pluronic F127/PEG | 181 | | 癌症疫苗 | 人黑色素瘤抗原(Trp2)和佐剂(CpG) | 涂层微针 | PLLA | 182 | | 癌症疫苗 | 微粒化卵巢癌疫苗 | AdminPen™(空心微针) | 不锈钢 | 183 | | 癌症疫苗 | B16F10癌细胞全细胞裂解物、GM-CSF | 可溶微针 | HA | 184 | | 癌症疫苗 | 小鼠乳腺癌全细胞裂解物 | 固体微针 | 金属 | 185 | | 癌症疫苗 | S-91黑色素瘤癌细胞疫苗抗原 | 固体微针 | Dermaroller | 186 | | 癌症疫苗 | HPV E743-63合成长肽 | 空心微针 | 二氧化硅毛细管 | 63 | | 基因治疗 | 八精氨酸/BRAF siRNA | 涂层微针 | 不锈钢 | 187 | | 基因治疗 | 质粒OVA和poly(I:C) | 可溶微针 | 阳离子多肽和PEG | 188 | | 检查点抑制剂 | aPD-1 | 可溶微针 | HA | 189 | | 检查点抑制剂 | aPD-1 | 空心微针 | PVP/PVA | 190 | | 检查点抑制剂 | aCTLA-4 | 可溶微针 | PVP | 191 | | 检查点抑制剂 | aPD-1和1-甲基-d,l-色氨酸 | 可溶微针 | HA | 192 | | 检查点抑制剂 | aCTLA-4和锌酞菁 | 可溶微针 | HA | 193 | | 检查点抑制剂 | 1-甲基-d,l-色氨酸和ICG | 可溶微针 | HA、PVP、PVA | 194 |

aPD-1:抗程序性细胞死亡蛋白1抗体;aPD-L1:抗程序性死亡配体1抗体;aCTLA-4:抗细胞毒性T淋巴细胞相关蛋白4抗体;ICG:吲哚菁绿。

治疗性癌症疫苗代表了一种利用患者自身免疫系统对癌症进行主动免疫治疗的可行选择,包括细胞疫苗(肿瘤或免疫细胞)、基因(DNA、RNA和病毒)疫苗和基于蛋白质/多肽的疫苗^195^。通过微针进行抗原疫苗接种可以产生强效的抗原特异性细胞免疫反应。通过激活抗原特异性CD8细胞毒性T淋巴细胞,它可以有效消除肿瘤,就像感染性疾病中身体的完全疫苗接种保护一样^118^。

免疫佐剂可以与抗原同时或提前使用,可以非特异性地增强身体对抗原的免疫反应。Kim等人^181^利用可溶微针将模型抗原(OVA)和免疫刺激佐剂(瑞喹莫德)递送至淋巴结,以成熟和激活抗原呈递细胞(图6)。基于两亲性三嵌段共聚物的可溶微针在皮肤中溶解后可原位生成纳米胶束,促进了难水溶性瑞喹莫德的递送。抗肿瘤免疫反应的结果表明,将含有OVA和瑞喹莫德的可溶微针应用于荷瘤小鼠诱导了显著水平的抗原特异性细胞和体液免疫^181^。

**图6.** 含有OVA和瑞喹莫德(R848)的原位纳米胶束生成可溶微针增强癌症疫苗接种。经参考文献^181^许可转载。© 2018,美国化学会。

具有催化能力的蛋白质和多肽可作为其他治疗方式的佐剂或作为抗癌药物本身^196^。同时,某些蛋白质和多肽由于其生物相容性和生物可吸收性也可作为药物递送载体。一些细胞穿透肽可以与疫苗结合用于免疫治疗。Ruan等人^187^开发了一种基于细胞穿透肽八精氨酸纳米复合物与涂层微针结合的siBraf递送系统,用于靶向抗黑色素瘤治疗。结果表明,八精氨酸比聚乙烯亚胺表现出更低的细胞毒性,同时表现出相当的基因转染和沉默效率。八精氨酸/siBraf涂层微针可以成功穿透到黑色素瘤部位并有效抑制肿瘤生长^187^。Duong等人^188^开发了一种基于可溶微针的多肽混合物以增强癌症免疫治疗。与皮下疫苗接种相比,可溶微针诱导了更高的OVA特异性抗体滴度并显著抑制了OVA表达的转移性肿瘤。

免疫调节抗体可以诱导强效的抗肿瘤免疫反应。然而,它们通常会产生大量的自身免疫,导致不良影响^197^。在所需细胞类型中靶向和控制释放抗体可以实现最小的脱靶效应并降低毒性。微针可以直接在局部疾病部位积累足够的免疫治疗剂,以有效靶向所需的肿瘤和免疫细胞。因此,将微针与免疫调节抗体整合是对抗恶性肿瘤的有前景的方法。

特别是,已设计纳米颗粒包封的微针以实现免疫检查点抑制剂的可控释放,包括aPD-1/aPD-L1^189,190^、aCTLA-4^191,194^和1-甲基-D,L-色氨酸^192,194^。Wang等人^189^开发了一种用于持续递送aPD-1的自降解微针。透明质酸与含有aPD-1和GOx的pH敏感葡聚糖纳米颗粒被配制到微针中。肿瘤酸性微环境促进了aPD-1的持续释放。小鼠黑色素瘤模型的体内抗肿瘤研究表明,与没有降解触发器的微针或瘤内注射游离aPD-1相比,应用自降解微针诱导了强烈的免疫反应^189^。

共载不同检查点抑制剂的微针实现了肿瘤的协同治疗^189,192^。Ye等人^192^构建了微针平台以共递送aPD-1和1-甲基-D,L-色氨酸。结果表明,协同治疗增强了B16F10黑色素瘤模型中有效的T细胞免疫^192^。

基于微针的药物递送通常依赖于被动扩散,这可能限制治疗剂的分布和渗透深度。Lopez-Ramirez等人^191^将镁颗粒加载到微针中作为内置引擎,以实现更快和更深的皮内药物递送(图7)。镁颗粒可以与组织间液反应快速产生H₂气泡,从而提供极高的局部高流体流动以突破皮肤屏障并增强局部有效载荷递送^191^。体内抗肿瘤实验显示,递送治疗性aCTLA-4的被动微针最初延迟了B16F10黑色素瘤的肿瘤生长。然而,到第46天,该组所有小鼠显示出超过1500 mm³的肿瘤负荷。形成鲜明对比的是,60%的用活性微针治疗的小鼠表现出完全无瘤状态^191^。

**图7.** 具有增强药物递送的内置活性微针贴片。(A)活性微针贴片的设计和机制示意图。(B)不同微针在pH 6.0下的药物释放动力学。(C)aCTLA-4的相应释放百分比。(D)从俯视图获得的微针贴片的荧光图像。(i)空白微针,(ii)FITC加载的微针,和(iii)FITC加载的活性微针。比例尺,1 mm。经参考文献^191^许可转载。© 2019,John Wiley and Sons。

基于微针的免疫检查点阻断治疗可以与其他癌症疗法相结合。此外,皮肤免疫系统的激活可以局部和全身性地增强抗癌免疫^190,194^。Chen等人^190^开发了结合检查点抑制剂和冷大气等离子体的空心微针。冷大气等离子体诱导肿瘤细胞死亡,释放的肿瘤相关抗原随后启动免疫反应。同时,从空心微针贴片释放的aPD-L1进一步增强了抗肿瘤免疫。

免疫治疗与光疗联合使用也进一步增强抗癌效果^190^。Chen等人^193^设计了一种用于协同光动力和免疫治疗的微针辅助平台,同时包封了疏水性锌酞菁和亲水性aCTLA-4。在这种方法中,光动力疗法首先杀死肿瘤并触发免疫反应,随后用aCTLA-4促进强效免疫治疗^193^。我们课题组^194^还设计了一种核壳结构微针,通过结合光热疗法和免疫治疗来增强免疫反应。所获得的系统可以有效根除原发性黑色素瘤肿瘤并抑制转移性肿瘤^194^。

除免疫治疗外,蛋白质还可以通过其他疗法发挥抗癌作用。例如,贝伐珠单抗可通过抑制肿瘤血管生成用于治疗多种癌症。Courtenay等人^198^使用微针提供了高剂量贝伐珠单抗的经皮递送,突出了微针向全身和淋巴循环提供持续药物递送的潜力。总之,微针辅助的蛋白质和多肽递送用于癌症治疗是一种有用的策略。

### 3.4 其他疾病治疗

微针介导的蛋白多肽经皮递送也可用于其他疾病治疗,如低血糖^199^、骨质疏松^200^、美容^45^和伤口愈合^201^。

胰岛素给药可能导致低血糖,这是一种以血糖水平异常低为特征的危及生命的疾病^202^。为解决此问题,GhavamiNejad等人^199^设计了一种智能微针贴片,在低血糖条件下特异性释放胰高血糖素。该微针贴片由光交联甲基化透明质酸包埋多功能微凝胶制备,实现了低血糖触发的释放特性(图8)。在1型糖尿病大鼠模型中,微针贴片成功预防了胰岛素过量引起的低血糖^199^。

**图8.** 微针贴片控制胰高血糖素释放的示意图。(A)微针贴片的制备过程。(B)微针贴片胰高血糖素释放的机制。经参考文献^199^许可转载。© 2019,John Wiley and Sons。

Naito等人^200^设计了一种装载人甲状旁腺激素的可溶微针贴片用于治疗骨质疏松。与溶液相比,微针明显改善了甲状旁腺激素的稳定性。体内研究表明,载甲状旁腺激素微针的生物利用度相对于皮下注射为100±4%。在骨质疏松大鼠模型中,载甲状旁腺激素微针成功抑制了骨密度的下降。

蛋白质和多肽在美容应用中发挥重要作用。Mohammed等人^45^研究了不锈钢微针对不同链长肽(包括黑色素抑素、rigin和棕榈酰五肽)皮肤渗透的影响。他们观察到较小分子量的肽与局部递送增强相关^45^。Chi等人^201^开发了包封血管内皮生长因子的壳聚糖微针以促进伤口愈合。药物释放可以通过伤口部位炎症反应引起的温度升高来控制。体外抗菌试验和体内伤口愈合研究表明,微针贴片可以促进伤口闭合过程中的胶原沉积、炎症抑制和组织再生^201^。

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## 4. 微针介导的蛋白多肽递送的临床应用

如上所述,基础研究已证明微针介导的蛋白多肽递送的可行性和优势。目前,许多基于微针介导的蛋白多肽药物经皮递送的疗法已进入临床应用。如表3所示,目前大多数活跃的临床试验集中于感染性疾病疫苗接种和糖尿病治疗的胰岛素递送。这些临床试验主要利用空心微针输注系统,少数研究了可溶或涂层微针。这主要是因为涂层微针、可溶微针或水凝胶微针的研究起步较晚,通常需要更复杂的微针设计和制造技术。微加工与药物研究之间的跨学科鸿沟也延缓了药物递送的发展^23^。

在此阶段,该领域正处于一个重要的转折点。更多微针产品将在不久的将来转化为临床和医疗实践。

**表3.** 微针用于治疗性蛋白多肽递送的当前活跃临床试验。

| 疾病或病症 | 治疗剂 | 微针类型 | 临床阶段 | NCT编号 | |-----------|--------|---------|---------|---------| | 流感 | 灭活流感疫苗(IIV) | 可溶微针 | 1 | NCT02438423 | | 流感 | 三价流感疫苗 | 空心微针 | 1/2 | NCT01707602 | | 流感 | Intanza®微针注射系统 | 4 | NCT01368796 | | 流感 | S-OIV H1N1疫苗 | MicronJet 600(空心微针) | 不适用 | NCT01049490 | | 流感 | 流感疫苗(TIV 2010/2011) | 微针装置(空心微针) | 不适用 | NCT01304563 | | 流感 | 流感疫苗 | 微针注射器(空心微针) | 不适用 | NCT00558649 | | 健康 | H1N1大流行性流感 | 微针装置 | 不适用 | NCT01039623 | | 麻疹和风疹 | 麻疹风疹疫苗 | 可溶微针 | 1/2 | NCT04394689 | | 肾衰竭 | HBV疫苗 | 新型皮内微针 | 2/3 | NCT02621112 | | 带状疱疹感染 | Zostavax | 新型皮内微针 | 2/3 | NCT02329457 | | 特应性皮炎 | Fluzone®皮内 | 超细微针 | 1 | NCT01518478 | | 特应性皮炎 | Fluzone®皮内 | 超细微针 | 不适用 | NCT01737710 | | 皮内注射 | 胰岛素 | MicronJet(空心微针) | 1 | NCT00602914 | | 糖尿病 | 胰岛素 | 空心微针 | 1/2 | NCT01061216 | | 糖尿病 | 胰岛素 | 空心微针 | 2/3 | NCT00837512 | | 糖尿病 | C19-A3 GNP肽 | Nanopass微针 | 1 | NCT02837094 | | 糖尿病 | 胰岛素和胰高血糖素 | MicronJet(空心微针) | 2 | NCT01684956 | | 低血糖 | 胰高血糖素 | 微针贴片系统 | 1 | NCT02459938 | | 绝经后骨质疏松 | 阿巴洛肽 | 固体微结构透皮系统 | 3 | NCT04064411 | | 绝经后骨质疏松 | 阿巴洛肽 | 涂层透皮微阵列 | 2 | NCT01674621 | | 绝经后骨质疏松 | Zosano Pharma甲状旁腺激素 | 涂层微针 | 1 | NCT02478879 | | 原发性腋窝多汗症 | A型肉毒毒素 | 点阵微针射频 | 不适用 | NCT03054480 | | 脊髓灰质炎 | 分数IPV | MicronJet600(空心微针) | 3 | NCT01813604 | | 自身免疫/自身炎症性疾病 | 阿达木单抗 | MicronJet600(空心微针) | 1/2 | NCT03607903 |

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## 5. 结论与展望

与小分子相比,蛋白质和多肽具有高特异性和高活性,已被证明对治疗多种疾病有效。然而,由于蛋白质和多肽的固有特性,如大分子量、稳定性差和构象柔性,它们通常通过注射给药,这不方便且不友好。微针可以改善患者依从性,克服蛋白多肽类药物的皮肤屏障。

微针已开发出多种设计和不同的递送策略,通常可分为固体微针、涂层微针、空心微针、可溶微针和水凝胶微针。皮肤在生物学和免疫调节中发挥着独特的作用。皮肤中的活跃免疫环境与微针介导的疫苗递送协同作用,以对抗感染性疾病和治疗癌症。这也是微针在糖尿病治疗中的重要应用,微针还使更安全的闭环葡萄糖响应疗法成为可能。微针介导的检查点抑制剂经皮递送减少了其脱靶效应,实现了局部靶向递送以治疗浅表癌症。总之,微针是治疗各种疾病的蛋白多肽递送的一种非常有前景的策略。

蛋白质和多肽的成功制剂取决于对其物理化学和生物特性的全面了解。值得注意的是,蛋白质和多肽的制剂和处理需要特别关注以优化其稳定性和功效。解决包括微针载药量、药代动力学和药效学特征、安全性和储存等基础问题的研究将促进蛋白多肽类药物的经皮递送。

随着可用于设计微针的微加工技术方面已取得的进步,更智能的微针系统将逐渐出现。蛋白质和多肽是强效的活性药物成分,可能突破微针低载药量的限制。包括体内外在内的综合表征方法已被用于评估微针安全有效地将药物递送到皮肤中的能力。该领域目前使用的方法将为未来开发微针评估的标准化方案铺平道路^97^。

乐观地预计,广泛的学术研究与制药行业相结合,将进一步加速微针介导的蛋白多肽药物经皮递送的临床转化。

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## 致谢

本研究由国家自然科学基金(项目编号:81803466,中国)、广东省澳门联合创新资助项目(项目编号:2020A050515009,中国)、广东省重点领域研发计划(项目编号:2019B020204002,中国)和广东省中医药局基金(项目编号:20191057,中国)资助。

## 作者贡献

权桂兰、潘昕和吴传斌构思了本综述。刘婷在陈明龙、傅金涛、孙颖和陆超的协助下撰写了手稿。陈明龙、权桂兰和潘昕修订了手稿。所有作者均已阅读并批准最终手稿。

## 利益冲突

作者声明无利益冲突。

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**脚注**

同行评审由中国药学会和中国医学科学院药物研究所负责。

**通讯作者信息**

权桂兰,电子邮件:xiaoplanet@163.com。 潘昕,电子邮件:panxin2@mail.sysu.edu.cn。