Periodontitis is a chronic inflammatory disease induced by biofilm accumulation, characterized by gingival inflammation and alveolar bone loss surrounding the teeth. It is the primary cause for tooth loss, affecting nearly half of the population aged 30 years and older (approximately 60.7 million individuals) in the United States. Specifically, severe periodontitis affects over one billion people globally (1–3). The global economic burden attributable to productivity losses resulting from periodontitis has been estimated at approximately $54 billion per year in direct treatment costs (2–4). It is critical to address the underlying pathological mechanisms to prevent and treat periodontitis. The main causes of periodontal diseases stem from bacterial dysbiosis and are further mediated by the host response to the bacteria (5–7). Although initiated by microbial dysbiosis, the progression and severity of periodontitis are largely determined by an exaggerated and unresolved host immune response, marked by excessive pro-inflammatory cytokine production, osteoclastogenesis, and failure of inflammation resolution pathways. For decades, mechanical debridement has been the primary method for biofilm removal in periodontal therapy. While effective in many patients, this strategy often demonstrates limited success in individuals with advanced or aggressive disease phenotypes, where hyperinflammatory host responses persist despite microbial control. Such observations underscore the critical role of immune dysregulation in periodontal disease progression and highlight the limitations of therapies that target bacteria alone. Therefore, restoring an appropriate host immune response is crucial for effective treatment; however, there is currently no established host modulation therapy (HMT) has proven to be effective. Therefore, over the past two decades, there has been a growing trend towards developing new therapies that target the exacerbation of the immune response in patients with periodontitis. Non-steroidal anti-inflammatory drugs (NSAIDs) have been utilized in the management of periodontitis, demonstrating some favorable clinical outcomes (8–10). However, there are significant concerns about long-term use because of multiple adverse effects, and the rebound of disease after stopping treatment has become a major drawback (11). Systemic anti-cytokine therapies, targeting specific cytokines to reduce inflammation, have been extensively investigated; however, their efficacy appears to be confined to periodontitis patients with underlying autoimmune disorders. Moreover, concerns exist regarding potential adverse effects, including an increased risk of infection and malignancy (12, 13).

In recent years, we have witnessed the rapid development of utilizing engineered viruses and bacteria, such as Limosilactobacillus reuteri (L. reuteri; previously known as Lactobacillus reuteri), Lactobacillus plantarum, and Lactobacillus brevis, to treat inflammatory diseases. These organisms are lactic acid bacteria (LAB) colonizing the mammalian gastrointestinal tract and oral cavity and serve as a delivery vector for anti-cytokine agents (14). For example, L. reuteri exhibits a range of probiotic properties, notably by attenuating the synthesis of pro-inflammatory cytokines and facilitating the development and functioning of regulatory T cells (15). It is utilized in the treatment of cancer immunotherapy as well as chronic inflammatory diseases, including inflammatory bowel disease, Crohn’s disease, and tissue fibrosis, in both pre-clinical and clinical studies (16–20). Furthermore, LAB administration has been demonstrated to mitigate bone loss in murine periodontitis models (21). In clinical investigations, oral intake of L. reuteri has been associated with decreased levels of periodontal pathogens and an inhibitory effect on periodontal inflammation (22–24), without eliciting adverse effects. However, these organisms are not yet widely used in clinical practice for treating oral diseases. A significant obstacle is the inability to effectively deliver and retain these bacteria within diseased tissues in vivo. This review focuses on the current use of HMT in inflammatory diseases, especially periodontitis, and explores the challenges linked to HMT. It also covers innovative technologies such as engineered bacteria, which could help bridge gaps in translation, improve therapeutic approaches, and deepen our understanding of this emerging field.

An imbalance in host immune function causes several diseases, including Crohn’s disease, tissue fibrosis, rheumatoid arthritis, diabetes mellitus, and various types of cancer. HMT constitutes a therapeutic paradigm that endeavors to modify the physiological state or functional capacity of the host organism as a strategic approach to disease management. Over the last decade, extensive experiments have been conducted on various immunomodulatory and microbiome-based strategies to combat inflammation-driven and immune-related diseases. Recently, novel approaches have demonstrated promising results. Zanin-Zhorov and Blazar reviewed the pivotal role of Rho-associated coiled-coil containing protein kinase 2 (ROCK2) in immune dysregulation and fibrosis in chronic graft-versus-host disease (cGVHD), highlighting how its selective inhibition via belumosudil not only restored Treg/Th17 balance but also showed over 70% response in refractory cGVHD patients (25). In parallel, Lu et al. emphasized Serum and Glucocorticoid Regulated Kinase 1 (SGK1) as another fibrosis-driving molecule in cGVHD, influencing T-cell differentiation and promoting tissue fibrosis. The use of SGK1 inhibitors as an immune modulator has shown promise in reversing fibrotic changes (26). As for cancer immunotherapy, Gao et al. found that the probiotic Lacticaseibacillus rhamnosus Probio-M9 enhanced anti-Programmed Cell Death Protein-1(PD-1) efficacy in colorectal cancer by modulating gut microbiota, enriching beneficial microbes, and increasing tumor-infiltrating cytotoxic T-cells (27). Complementing this, Fong et al. reviewed broader strategies, such as probiotics, prebiotics, and fecal microbiota transplantation (FMT), for colorectal cancer prevention and treatment, emphasizing the dual roles of microbiota in modulating inflammation and chemoresistance (28). Focusing on cystic fibrosis, Bedi et al. uncovered how Pseudomonas aeruginosa exploits endoplasmic reticulum stress pathways, particularly via CCAAT/enhancer-binding protein homologous protein (CHOP)-mediated suppression of peroxisome proliferator-activated receptor gamma (PPARγ), to impair epithelial host defenses, and proposed PPARγ agonists, such as pioglitazone, to restore immune balance (29). Gowen et al. underscored the potential of precision microbiome therapeutics, discussing how interkingdom microbial interactions and biofilm dynamics influence host immunity and suggesting personalized probiotic development as a next-generation disease treatment strategy (30).

Despite promising outcomes, significant challenges remain in the application of immune-targeted treatments. Pathway inhibitors, such as ROCK2 and SGK1, show therapeutic potential in cGVHD, yet their broad roles in tissue homeostasis and metabolism raise concerns about off-target and systemic effects, necessitating isoform-specific targeting and dose refinement (25, 26). In cancer immunotherapy, microbiota modulation via probiotics or fecal transplantation enhances efficacy but faces hurdles of strain-specificity, variable host microbiomes, pathogen transmission, and regulatory oversight, underscoring the need for personalized and standardized approaches (27). Novel strategies, such as β–glucan–induced trained innate immunity, highlight the difficulty of balancing enhanced host defense with the risk of autoimmunity. Meanwhile, metabolic regulators, including PPARγ agonists in cystic fibrosis, carry systemic side effects that limit their chronic use. Furthermore, the complexity of microbiota–host interactions, including biofilm dynamics and interkingdom signaling, complicates the predictability of responses in diseases like Crohn’s, emphasizing the necessity for precision-engineered and scalable microbial therapeutics (29–31).

While these approaches appear promising, it can be challenging to anchor these advances to oral diseases because of the distinct immunological and microbial landscape of the oral environment. The oral cavity is characterized by constant mechanical stress, a polymicrobial biofilm, and a rapidly responsive and complex immune environment. While all challenges, such as systemic effects from pathway modification, interindividual variability, and durability of probiotic colonization, remained, it is even more difficult to balance microbiota and immune responses to achieve immune modulation without disrupting oral mucosal homeostasis. Collectively, while systemic inflammatory disease models provide valuable mechanistic frameworks, successfully adapting these therapies for oral diseases will require careful consideration of the specific immunological and microbial conditions present in the oral cavity.

In the context of periodontitis, HMTs have been investigated for nearly three decades to counteract microbial dysbiosis and attenuate destructive inflammatory processes. This therapeutic approach focuses on modulating the host immune response to foster an environment conducive to a balanced oral microbiome while suppressing the exaggerated inflammatory reactions that contribute to periodontal tissue breakdown (32–35). Various strategies have been employed to modulate the immune response, aiming to reduce tissue damage, maintain a balanced environment between pro-inflammatory and anti-inflammatory mediators, and promote the resolution of inflammation and periodontal tissue repair (34).

There have been established and emerging host-modulation strategies in the context of systemic and oral diseases. With the focus on periodontitis, this review delineates the mechanisms of action and limitations of several HMTs—including NSAIDs, SPMs, sub-antimicrobial dose doxycycline, cytokine-based treatments, and probiotics—highlighting their measurable yet often limited benefits, which are constrained by factors such as short half-life, systemic effects, treatment rebound, and variability in clinical outcomes (11, 33) (Table 1). Recently, novel technologies, including microneedle-based delivery systems, cytokine-secreting cell-encapsulation platforms, IL-10-based gene therapy, and engineered bacterial therapeutics, have been utilized in HMTs (23, 53, 68). These emerging interventions demonstrate promising efficacy in preclinical models of inflammatory and immune-mediated diseases, but they are still in the early stages of translation to periodontal therapy (73). Future research directions may encompass the optimization of localized delivery systems for enhanced stability and sustained release, refinement of anti-inflammatory mediator or cytokine therapies through combinatorial strategies or improved vectors, development of engineered probiotics capable of targeted colonization and in situ therapeutic molecule production, integration of microbial and immune-modulatory approaches, execution of long-term clinical trials to assess safety and durability, and the resolution of regulatory and safety challenges related to gene- and microbe-based therapeutics.