SFTSV is classified within order Bunyavirales, family Phenuiviridae, and genus Bandavirus. The viral particles exhibit a spherical icosahedral structure with a diameter of approximately 80–120 nm and are enveloped in a lipid bilayer membrane derived from the host cell membrane. Cryo-electron microscopy has revealed that the surface of SFTSV is covered with penton and hexon spikes, containing a total of 720 Gn-Gc heterodimers (26). SFTSV is a single-stranded, negative-strand RNA virus. Its genome consists of three fragments: small, medium, and large, containing 1,744, 3,378, and 6,368 nucleotides, respectively (2). Segment L encodes RNA-dependent RNA polymerase (RdRp) required for viral replication and transcription. Structural analysis of the L protein, covering approximately 70% of its sequence, reveals a conserved RdRp domain, an endonuclease domain connected by a flexible linker region, and a cap-binding domain (CBD). Functional assays have demonstrated that the L protein must concurrently bind to the 3’ and 5’ promoter RNAs of the viral genome to activate its Mg²⁺/Mn²⁺-dependent polymerase, facilitating replication through terminal initiation (27). The medium segment (M) encodes the precursors of glycoproteins Gn and Gc, which are cleaved into two glycoproteins, Gn and Gc, that play crucial roles in viral particle assembly and entry into host cells. The small segment (S) encodes the non-structural protein (NS) in the forward direction and the nucleoprotein (NP) in the reverse direction, with a 62-base pair spacer region between them. The NP forms a hexamer and interacts with viral RNA to form viral ribonucleoprotein (RNP) (2).

SFTSV demonstrates considerable genetic diversity, with multiple genotypes primarily identified through whole-genome sequencing and phylogenetic analysis. Despite this, a universally accepted genomic typing and nomenclature system has not yet been established. Initial research categorized SFTSV into five genotypes, labeled A-E (28, 29). Subsequent investigations refined this classification to six genotypes, A-F (30–32), which has become the more commonly used classification method. Alternative classification frameworks have also been proposed, including a system that organizes the virus into three lineages, I-III, with lineage I further divided into two sublineages (33), and another that divides the virus into two clades, C and J, forming eight genotypes: C1-C5 and J1-J3 (34). Additionally, another study identified seven distinct branches, comprising five Chinese lineages (I, II, III, IV, and V) and two Japanese lineages (VI and VII) (35).

There is evidence suggesting potential correlations between specific genotypes and clinical pathogenicity (36). For instance, analysis of case fatality rates among different genotypes reveals that the B2 genotype is associated with higher mortality (37), which may partially account for the increased death rates observed in South Korea and Japan, where B-type epidemics are prevalent.

Association analyses between clinical indicators and genotypes have demonstrated that certain genotypes linked to increased mortality rates may provoke more robust inflammatory responses (35, 38). Research indicates that patients classified within the Clade IV branch are at a heightened risk of mortality, exhibiting significantly elevated levels of inflammatory mediators compared to other branches. A distinctive co-mutation pattern within this branch is associated with an increased risk of mortality and pronounced inflammatory responses (35). At the molecular level, variations in the M gene fragment are posited to play a pivotal role in the observed genotypic differences (38–40). These mutations are likely intricately linked to the virus’s mechanisms of immune evasion and host adaptation. For example, the V506M mutation in the Gn glycoprotein region of the M fragment from the A genotype strain in Henan Province, China, has been implicated in adverse clinical outcomes (41). Additionally, a study focusing on various subclones of the SFTSV strain YG1 identified the R624W mutation in the Gc protein as a critical site influencing the virus’s low pH-dependent cell fusion (42). The evolutionary rates of SFTSV’s three genomic segments (L, M, and S) also vary, with the S segment evolving most rapidly and exhibiting the strongest adaptive capacity (43). Overall, SFTSV shows relatively conserved evolution. However, due to factors such as tick vectors, climate change, and human agricultural activities, enhanced surveillance remains essential.

Calcium channel blockers (CCBs), besides their extensive application in cardiovascular and cerebrovascular disorders, have been found to have antiviral activity against a number of lethal viruses, including hantaviruses (128), Ebola viruses (129), Marburg viruses (130), and SFTSV. In vitro studies indicate that CCBs such as benidipine hydrochloride and nifedipine exhibit dose-dependent inhibitory effects against SFTSV, primarily through the inhibition of calcium ion influx and reduction of intracellular Ca²⁺ concentration. Calcium-free medium, calcium chelator (BAPTA-AM), or knockdown of the L-type calcium channel Cav1.2 gene inhibited viral replication, confirming that calcium channels are a key target (131). A clinical case report of a 67-year-old male patient who failed steroid therapy and progressed to hemophagocytic lymphohistiocytosis (HLH) recovered completely and without complications after receiving supportive care combined with intravenous nicardipine for hypertension, suggesting that the drug may be beneficial for his recovery (132). Loperamide (133) and manidipine (134) exert their anti-SFTSV effects by inhibiting the replication phase of the virus after entry into the host cell. Among them, manidipine is effective in vitro and in vivo, with broad-spectrum activity against a wide range of negative-stranded RNA viruses and the capacity to inhibit inclusion body formation induced by viral nucleocapsid proteins (134). Mechanistic studies have shown that calcium ions play an important role in viral replication, influencing both endocytosis and the regulation of calcium-modulated calcineurin-NFAT pathway and actin dynamic equilibrium (134).

Neutralizing antibodies (nAbs) function as passive antiviral agents, contributing to prevention, therapeutic interventions, and the guidance of vaccine design (177). They impede viral entry by binding to functional entry molecules on the viral surface and elimination of infected cells through Fc-mediated in vivo effects (177). In convalescent serum from patients with SFTS, neutralizing antibodies can persist for up to a decade, although they exhibit considerable individual variability, thereby necessitating personalized monitoring (178).

Research indicates that the humoral immune response derived from convalescent patients primarily targets the highly immunogenic nucleocapsid protein. Despite the lack of direct neutralizing activity, these antibodies present potential utility for early diagnosis (179–181). The ¹¹¹In-labeled N protein monoclonal antibody probe ([¹¹¹In]In-DTPA-N-mAb) serves as a novel imaging probe. Through SPECT/CT, it facilitates non-invasive and precise visualization of SFTSV infection dynamics within the spleens of mice. This methodology holds significant promise as a powerful instrument for advancing the understanding of SFTSV pathogenesis, screening antiviral drugs, and achieving accurate clinical diagnosis and treatment (182).

The M segment of SFTSV encodes the glycoprotein precursor, which is cleaved into Gn and Gc (2). Gn plays a primary role in binding to host receptors (177). Structurally, the head of Gn adopts a compact triangular conformation, consisting of three subdomains (I, II, III) (183). Domain I (DI) serves as an ideal target for developing broad-spectrum neutralizing antibodies (184). Key neutralizing antibodies targeting DI include S2A5 (185), whose light chain complementarity-determining region L1 (CDR-L1) cross-linking mechanism enhances neutralizing efficacy. 40C10 (186) impedes viral internalization and demonstrates efficacy with delayed administration. Its humanized variant HAb-23 holds clinical potential (187). JK-8 achieves broad-spectrum protection at low doses by inhibiting Gn-CCR2 interaction (188).

Other neutralizing antibodies targeting Gn include human monoclonal antibodies hmAbs1F6, 1B2, and 4–5 derived from convalescent SFTS patient lymphocytes, which provide complete protection in murine models when used in combination (189). The bispecific antibodies bsAb1/bsAb3, which simultaneously target the Gn and Gc epitopes, exhibit neutralizing efficacy exceeding 100-fold higher than their parent antibodies and effectively inhibit viral escape modifications (184). The findings indicate that combination of antibodies targeting distinct epitopes might markedly enhance the antiviral activity of neutralizing antibodies. MAb 4-5, a humanized neutralizing monoclonal antibody derived from convalescent patients, specifically binds to the α6-helix of Domain III via its heavy chain CDR H3 to inhibit Gn-cell receptor interaction (183, 190). And Ab10 targets the DII and stem regions to inhibit membrane fusion. This antibody exhibits a strong affinity for its targets and is efficacious against the vast majority of epidemic strains, with in vitro neutralizing activity superior to that of antibody MAb4-5 (191).

In addition to the aforementioned antibodies, the production of highly effective antiviral antibodies utilizing various advanced technology platforms has shown considerable therapeutic promise and intriguing applications. The mRNA-LNP-delivered S/A-TEN antibody can be swiftly synthesized, and a low-dose, two-dose strategy provides 100% protection across multiple models while widely neutralizing viruses of different genotypes (192). Through high-throughput nanobody screening utilizing next-generation sequencing (NGS) and proteomics on camels immunized with Gn protein, a total of 19 candidate nanobody sequences were identified. Six of these were chosen for recombinant expression and purification, among which nanobody 57493 demonstrated strong affinity and specificity toward Gn protein (193). Another camel-derived single-domain antibody, SNB02, demonstrates exceptional efficacy both in vitro and in vivo. It not only suppresses viral replication but also alleviates infection-induced thrombocytopenia and multi-organ damage, demonstrating interesting application prospects (194).

In summary, neutralizing antibodies demonstrate multifaceted application potential: in SFTSV diagnosis, they concentrate on nucleocapsid protein applications; in therapeutics, they facilitate broad-spectrum neutralization by targeting glycoproteins (Table 1) and in pathological research, they elucidate infection mechanisms through in vivo dynamic tracing. Nonetheless, none of these therapeutic antibodies have undergone clinical confirmation, and their actual efficacy and safety necessitate comprehensive assessment.

The N-terminal endonuclease (endoN) of the L protein in SFTSV cleaves host mRNA through a “cap-snatching” mechanism to obtain the cap structure and initiate viral transcription (200). This endonuclease relies on Mn²⁺ as a cofactor, and mutations in critical catalytic residues (e.g., H80A, D112A, etc.) significantly diminish its enzymatic activity. Its α/β mixed-fold structure resembles that of most segmented Negative-sense RNA virus (sNSV) endonucleases, with the unique features including an N-terminal Beta-Cap responsible for maintaining structural stability and a C-terminal Dynamic α6 Helix associated with enzyme activity regulation (201). Due to endonuclease N’s critical function in viral replication and its conservation in sNSVs, it has emerged as a significant antiviral target. The influenza drug baloxavir marboxil (BXA) (201) and benzothiazole compounds (such as F1204 and F1781) (202) efficiently suppress SFTSV endonuclease activity by targeting metal ions at the endonuclease active site. The novel inhibitors Tanshinone I/IIA impede cap-cleavage by associating with the endonuclease domain (195). Licorice flavonoid C disrupts the active conformation through hydrogen bonding and hydrophobic interactions, noncompetitively inhibiting RNA cleavage (203). Both compounds demonstrate anti-SFTSV activity in vitro and in vivo.

Additionally, the NP encoded by the SFTSV S segment is involved in the release, replication, and assembly processes of the viral RNP complex. Due to its similarly conserved function, the N protein may likewise represent a potential target (204). lurasidone interferes with genomic replication by binding to NP (205). The host factor Moloney leukemia virus 10 protein (MOV10) directly inhibits RNP assembly by targeting the N-arm domain of the NP. This action is notably independent of MOV10’s RNA helicase function and the interferon pathway (206). Another host factor, the Myxovirus resistance protein A (MxA), inhibits RNP activity by disrupting the interaction between the viral NP and the RdRp (207). The mechanisms of action of the aforementioned host factors provide potential new targets for pharmacological research.

Antiviral peptides are naturally occurring or synthetically engineered small-molecule peptides that exert broad-spectrum antiviral effects by disrupting viral particles, obstructing viral entry, and inhibiting replication. They represent significant candidates for innovative antiviral pharmaceuticals. Structure-guided research demonstrates significant application potential. The structure-based virtual screening and validation process generally utilizes methodologies such as molecular dynamics simulations, alanine scanning, and peptide docking to identify potential inhibitors of SFTSV binding sites from FDA-approved drug libraries or established compound databases, or to design and synthesize novel antiviral peptides/small molecule compounds (205, 208–210). Subsequently, the intricate architectures of candidate compounds targeting viruses are clarified by structural biology methodologies, including X-ray crystallography and cryo-electron microscopy, which offer validation of interactions and atomic-level specifics. These high-resolution structural insights allow for in-depth analysis and identification of critical binding residues, which can inform therapeutic optimization to enhance potency (211, 212), thereby significantly decreasing the time and financial expenditures associated with drug development.

The computer-aided designed cyclic peptide HKU-P1 effectively binds to the SFTSV Gn protein, exerting a neutralizing effect during the viral entry phase. Its combination with favipiravir demonstrates synergistic antiviral activity. However, it exhibits typical constraints of peptide molecules, including low oral bioavailability, short half-life, and suboptimal ADME (Absorption, Distribution, Metabolism, Elimination) properties (211). Alongside methods aimed against the Gn protein, the antiviral peptides SGc1 and SGc8, derived from the viral Gc protein impede viral entrance by obstructing membrane fusion. They exhibit potent antiviral activity (IC₅₀ < 10 μM) in L02, Vero, and BHK21 cells, alongside minimal cytotoxicity, low immunogenicity, and robust stability within the temperature range of -20 °C and 37 °C. To alleviate protease degradation risks, SGc1 and SGc8 underwent N-acetylation and C-amidation modifications. However, although these modifications provided some advantages, they did not address the problem of low permeability. Furthermore, critical parameters such as the in vivo distribution and actual half-life of the modified peptides have yet to be evaluated in in vivo systems, like animal models (213). Research on the viral replication phase reveals that sphingomyelin synthase SMS1 catalyzes the synthesis of sphingomyelin SM (d18:1/16:1) within the Golgi apparatus. This sphingomyelin directly interacts with the helical-turn-helical motif of the viral RdRp protein, facilitating the formation of the viral replication complex. Studies indicate that increased SMS1 expression is associated with a heightened risk of serious disease in elderly individuals. WYFA15, an inhibitor designed to target SMS1 and optimized via molecular docking, effectively impeded the replication of several RNA viruses in both cellular and animal models while demonstrating favorable safety profile (212).

The profound integration of artificial intelligence (AI) with structural biology technologies holds promise for further advancing the optimization and development of peptide molecules and small-molecule inhibitors. It serves a crucial function in essential phases such as target identification, virtual screening, de novo design, ADMET (absorption, distribution, metabolism, excretion, and toxicity) and to prediction, synthetic planning, and automated synthesis, significantly accelerating the drug development process (214).

Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR) technology has been instrumental in identifying systemic host factors, confirming targets, clarifying mechanisms, and revolutionizing diagnostic methodologies. Through genome-wide CRISPR knockout screening, researchers have identified essential host factors, including LRP1 (54), SMS1 (212), and CCR2 (53). Antagonists targeting these host factors have demonstrated antiviral effects. CRISPR-engineered gene knockout cell models not only validate target functions but also provide foundational tools for in- comprehensive research of infection mechanisms. The A549 cell line, established by Dr. Liu’s team through CRISPR/Cas9 technology to knock out the clathrin heavy chain (CLTC), confirms that lipid raft-mediated endocytosis may be a key entry pathway for SFTSV (215). Furthermore, CRISPR-based validation revealed the essential role of p38α in viral replication, with its inhibitor SB203580 capable of reducing SFTSV viral RNA levels and infectious viral particle production (87). CRISPR technology has spawned multiple diagnostic applications. A dual-gene, single-tube detection system based on Cas12a/Cas13a enables highly sensitive and rapid on-site SFTSV diagnosis (216). The CasFAS live-cell RNA imaging system facilitates dynamic monitoring of viral RNA (217).

Antiviral medications can be roughly classified into two primary categories depending on their mechanisms: Virus-targeting antivirals (VTAs) and host-targeting antivirals (HTAs) (218). VTAs directly or indirectly target viral components, exerting effects by inhibiting viral entry, replication, or assembly, such as the key enzyme inhibitors and antiviral peptides previously outlined. HTAs target host proteins essential for the viral lifecycle, indirectly inhibiting viral proliferation by regulating host cellular processes (e.g., signaling pathways) or immune system functions. Anidulafungin obstructs viral internalization during the viral invasion phase by inhibiting the clathrin-mediated endocytosis pathway (219). Toosendanin targets the viral internalization process to exert its impact. The lack of resistance development after serial passage suggests it may achieve potent inhibition by regulating host factors such as calcium channels (220). Upon virus entry into the replication phase, badoxifene acetate (BZA) inhibits viral replication by upregulating the expression of the host genes GRASLND and CYP1A1 (221). Meanwhile, the Hedgehog pathway inhibitor HhAntag suppresses viral protein translation by downregulating GLI1 protein, which in turn downregulates the expression of its downstream targets S1PR1 and S1PR5 (222). Furthermore, the active component luteolin in the traditional Chinese medicine compound Qingqi Gushe Decoction (QQGX) effectively inhibits SFTSV replication by inducing cell S-phase arrest through targeting the CDK2-CCNA2 complex (223). Notably, the mechanism of action of the nanobody NbP45 centers on immune modulation. By blocking the PD-1/PD-L1 immune checkpoint pathway and reversing T-cell exhaustion, it enhances the body’s antiviral immune response, thereby decreasing SFTSV replication indirectly (224).

The primary advantages of HTA lie in its high drug resistance barrier and potential broad-spectrum efficacy, while VTA features direct action and rapid onset. Deepening host target discovery, developing synergistic combination strategies between VTA and HTA, and advancing the clinical translation of immunomodulatory therapies will be key directions for future antiviral research and development.

There exists a close interaction between metabolic disorders and viral infections. On one hand, metabolic dysregulation states can exacerbate the severity of SFTSV infection and influence prognosis (212, 225, 226). On the other hand, viral infection may trigger host metabolic dysfunction, establishing a detrimental loop (227–229). Therefore, interventions targeting critical metabolic pathways may offer a novel approach to improving the prognosis of viral infections. Metformin suppresses cellular autophagy via the AMPK-mTOR pathway, thereby reducing SFTSV viremia levels and mortality in patients with hyperglycemia (228). For patients with hypertension, the administration of CCB antihypertensive drugs, particularly nifedipine, helps mitigate disease severity, alleviate clinical symptoms, and reduce the risk of progression to severe SFTS (230). Lovastatin and fenofibrate, as approved lipid-lowering drugs, can inhibit SFTSV replication and hold potential for conversion into antiviral therapeutic drugs (231). Multiple studies indicate that host lipid metabolism is closely associated with viral infection and may function as an effective antiviral target (232, 233). Taurolithocholic acid (TLCA), a secondary bile acid, indirectly suppresses virus-induced ferroptosis by activating the TGR5-PI3K/AKT-SREBP2 signaling pathway, enhancing the expression of fatty acid desaturase 2 (FADS2). In vitro, it inhibits SFTSV replication and mitigates host inflammatory responses, thereby protecting mice against fatal infection (227). Supplementing with arginine increases platelet nitric oxide (Plt-NO) concentration, inhibits platelet activation, accelerates platelet recovery, and restores T-cell CD3-ζ chain expression. This promotes viral clearance and reduces liver injury marker (AST/ALT) levels. However, it did not significantly decrease mortality rate sand necessitates additional examination (226).

Combination therapy strategies demonstrate significant advantages in antiviral treatment by effectively suppressing viral replication through complementary or synergistic mechanisms. Combined use of ribavirin with interferon (IFNα/β/γ) significantly enhances antiviral efficacy and diminishes the necessary therapeutic dosages each drug. Experimental data indicate that this combination regimen at their respective EC₉₀ concentrations reduces viral titers by more than three log₁₀ levels, whereas monotherapy reduces titers by only about one log₁₀ level. Concurrently, the reduced required dosage decreases potential toxicity (234). Drugs that activate innate immune mechanisms, such as the vitamin D derivative alfacalcidol (122) and the immunomodulator tilorone (marketed as Amixin/Lavomax) (235), enhance the antiviral state of host cells, mitigate tissue damage, and lower mortality rates. When such immunomodulators are combined with the direct-acting RNA polymerase inhibitor T-705, their complementary mechanisms produce significant synergistic effects that far exceed the sum of their individual actions. This dual strategy of “immunomodulation plus direct antiviral action” offers a new therapeutic alternative to patients with SFTSV, particularly those with severe disease. Tocilizumab targets cytokine storms by blocking IL-6 receptors and synergistically inhibits core inflammatory pathways with corticosteroids, which possess broad-spectrum anti-inflammatory effects, thereby effectively controlling excessive inflammatory responses. Clinical data from critically ill patients show that, compared to corticosteroid monotherapy (14-day mortality rate of 39.2%), this combination regimen significantly reduces mortality to 11.8%, lowering the risk of death by 79%, and can serve as a treatment option for SFTS (236). Additionally, the combined use of interferon signal enhancers with recombinant interferon can mitigate its associated side effects by reducing the required dose of recombinant interferon needed to achieve optimal therapeutic efficacy. Studies indicate that the combination of kaempferide with low-dose IFN-β can enhance antiviral effects (162).

In summary, combination therapy strategies may broadly encompass the co-administration of virus-targeted and host-targeted drugs, the combination of immunomodulators and direct-acting antivirals, and multi-targeted drug combinations, demonstrating promising application potential. Future research should further explore combination therapy regimens. By combining drugs with different mechanisms of action, synergistic effects can be harnessed to enhance antiviral efficacy, reduce single-agent dosages to minimize cytotoxicity, and delay the emergence of drug resistance. With the application of AI technologies, researchers can extract key molecular features from massive experimental datasets to systematically identify synergistic or antagonistic relationships between drug combinations, significantly accelerating the discovery and development of novel drug combinations (237).

Research on SFTSV vaccines involves a variety of technical methodologies, such as DNA vaccines, attenuated live vaccines, viral vector vaccines, and mRNA vaccines. A multi-antigen DNA vaccine, designed based on a consensus sequence, has demonstrated the ability to induce strong neutralizing antibody and T cell responses at low doses in both murine and ferrets, resulting in complete protection from lethal SFTSV challenge. However, this approach necessitates the use of electroporation for delivery and requires multiple immunizations (238). Nanopatterning technology significantly enhances the loading capacity and coating efficiency of DNA vaccines by enhancing the hydrophilicity and biocompatibility of microneedles, without compromising DNA stability. In vivo studies demonstrate that this technology effectively elicits robust cellular immune responses, particularly from CD8+ T cells, indicating promising applications (239). In contrast, recombinant SFTSV attenuated live vaccines derived from the HB29 strain(genotype D) (rHB29NSsP₁₀₂A and rHB2912aaNSs) demonstrate the ability to induce cross-protection against B/D genotype strains following a single immunization dose, demonstrating favorable safety and genetic stability profiles. However, further evaluation is warranted concerning their potential risks in immunocompromised individuals, due to the theoretical risk of virulence reversion (240). A live attenuated recombinant vesicular stomatitis virus (rVSV)-based vaccine induces high titers of neutralizing antibodies against SFTSV after a single dose, provides cross-protection against HRTV, and demonstrates potential for post-exposure prophylaxis. Its favorable storage stability further increases practical applicability (241, 242). The rVSV vaccine expressing the glycoprotein of the SFTSV AH12 strain (genotype F) shows reduced replication in vitro and demonstrates a favorable safety profile in IFNAR^-/^- mouse models, while also inducing high-titer cross-neutralizing antibodies (241). Notably, vaccine derived from the HB29 strain (genotype D) generates a weaker neutralizing antibody response in immunocompetent C57BL/6 mice, indicating that its replication and subsequent immune response may be limited (242). The Ad5 (Adenovirus type 5) vector vaccine induces robust levels of neutralizing antibodies and Th1/Th2 responses through the expression of the Gn protein, achieving complete protection in immunodeficient models. Furthermore, Gn demonstrates superior immunogenicity compared to Gc or their co-expression (243). The bivalent rabies virus vector vaccine conferred highly effective protection against both RABV and SFTSV in mice (244). Furthermore, in a mouse model pre-vaccinated with the vaccinia virus, the m8 GPC and m8 N+GPC vaccines enhanced survival rates against lethal doses of SFTSV infection while mitigating tissue damage. This finding indicates the potential utility of such vaccines (245). Additionally, the self-replicating mRNA vaccine pJHL204225, which expresses SFTSV NP, Gn/Gc, and NS antigens and is constructed using the attenuated Salmonella JOL2500 vector, along with the dual expression system pJHL270/pJHL305226, which expresses SFTSV Gn/Gc epitopes and full-length glycoproteins in both prokaryotic and eukaryotic systems, can elicit balanced Th1/Th2 immune responses without the need for exogenous adjuvants. These vaccines generate high levels of antigen-specific IgG, IgM, and neutralizing antibodies, promote CD4+ and CD8+ T cell proliferation and cytokine secretion, and significantly reduce viral load while alleviating tissue damage in human C-type lectin receptor (hDC-SIGN) transgenic mouse challenge models, demonstrating potential for multi-antigen delivery. It is noteworthy that the type and intensity of immune responses elicited by various antigen combinations can differ significantly (246), and the size of the carrier may also affect antigen delivery efficiency and the rate of immune activation (247).

mRNA vaccines have gained prominence as a platform for vaccine due to their rapid development, favorable safety profile, and feasibility for large-scale production (248). mRNA-LNP vaccines targeting Gn and encapsulated in lipid nanoparticles (LNPs) induced potent humoral and cellular immune responses in mice (249). mRNA vaccines encoding full-length glycoproteins provide long-term protection lasting at least five months and confer cross-protection against other Bandaviruses, such as HRTV and GTV. These vaccines also induce robust Th1-biased cellular immune responses. It is important to note that, due to the current immaturity of large-scale mRNA synthesis technologies, using macromolecular proteins as antigens poses certain challenges during vaccine preparation (250). The multi-epitope mRNA vaccine incorporates conserved epitopes from the Gn, Gc, NP, and NSs proteins and utilizes computational design to achieve broad-spectrum immune coverage. However, predictive models indicate that this mRNA may interact with Toll-like receptor 3 (TLR3), which, while potentially enhancing immune activation, also carries the risk of inducing excessive inflammatory responses. Furthermore, the current findings are predominantly based on computational simulations, and their actual immunogenic effects and safety profiles require experimental validation (251).

In summary, SFTSV vaccine research is progressing rapidly through multiple collaborative technological platforms, demonstrating broad application potential. Beyond vaccine prevention strategies relying on neutralizing antibodies, the cellular immune mechanisms induced by vaccines also play a role in combating viral infections. Studies have reported that even non-envelope protein-specific T cell responses can provide some degree of immune protection (238), but further investigation is needed to elucidate the specific mechanisms involved. Despite significant progress to date, the path to clinical application for SFTSV vaccines remains fraught with challenges. Further optimization of antigen design, enhancement of antibody titers, improvement of vector system safety, validation of vaccine efficacy across multiple animal species, and assessment of vaccine coverage against viral variants are all necessary.