Chan and Abedon initially proposed that treatment strategies could be categorized based on the number of phage types employed: “monophage therapy” using a single phage type, and “polyphage therapy” involving multiple phage types (Chan and Abedon, 2012). Titze et al (Titze and Krömker, 2020). utilized a phage mixture (7.4 × 10⁹ PFU/mL) against S. aureus isolate 7142 with nuc gene-positive, resulting in a reduction of bacterial colonies by 4.2 log₁₀ CFU/mL after 12 h. Liu et al. (2022) isolated four distinct bacteriophages against drug-resistant S. aureus from various sources, namely nasal swabs, soil, and sheep feces: APTC-SA-2, APTC-SA-4, APTC-SA-12, and APTC-SA-13. Genome sequencing revealed that none of these bacteriophages contained virulence or antibiotic resistance genes. Sensitivity testing demonstrated that a single phage was effective against 80%-95% of S. aureus isolates, including 32 clinical MSSA, 17 MRSA isolates, and 2 ATCC strains. In contrast, the phage cocktail APTC-C-SA01, comprising four phages, exhibited sensitivity to over 98% of S. aureus isolates, displaying a strong complementary effect. Moreover, the frequency of phage-resistant mutants decreased from 0.12~0.21 × 10^–7 to 0.9 × 10^–9.

Studies have revealed that phages can reduce the minimal inhibitory concentration (MIC) of certain antibiotics and can act synergistically with antibiotics (Grygorcewicz et al., 2020; Gu Liu et al., 2020; Kebriaei et al., 2020a). The term phage-antibiotic synergy (PAS) was initially introduced by Comeau et al. (2007) to describe an accidental discovery where sublethal concentrations of antibiotics substantially increased the production of lytic phages by bacteria. This phenomenon was linked to the augmented biomass and biosynthetic capabilities of bacteria in the presence of antibiotic levels that were sufficient to hinder cell division without causing cell death. For the viruses, this led to a shorter latent period and a larger burst size, enabling quicker propagation and a decrease in the bacterial population. From an evolutionary perspective, the imposition of two distinct selective pressures on bacteria may reduce the likelihood of them developing potential resistance (Torres-Barceló and Hochberg, 2016). Furthermore, Gu Liu et al. (2020) revealed that phages can reduce the MIC required for bacterial strains that are already resistant to antibiotics. This effect depends on the type of antibiotic and the specific balance between the two agents, and it is significantly influenced by the host’s microenvironment. Prior studies have demonstrated the efficacy of combined phage-antibiotic therapy against S. aureus infections in vitro. For instance, Kebriaei et al. (2022) combined phage Sb-1 with daptomycin, resulting in a 2 log₁₀ CFU/mL reduction in MRSA biofilm colony counts compared to the use of a single antibiotic. Similarly, Simon et al. (2021) demonstrated synergistic effects between phage Sb-1 and oxacillin. Phage Sb-1 alone reduced MRSA levels by 35%, whereas in combination with oxacillin, it reduced MRSA levels by approximately 90%. Likewise, Joo et al. (2023) confirmed that the combined application of vancomycin and bacteriophage K, compared with vancomycin or bacteriophage K alone, reduced MRSA in biofilm to less than 2 log₁₀ CFU/mL, indicating significant synergy.

In a study conducted by Teng Fei et al. (Teng et al., 2022) using a mouse model, a phage treatment group (with a concentration of 1 × 10⁸ PFU/mL) and a ceftiofur sodium treatment group (with a dosage of 5 mg/kg) were compared. The results showed that the phage therapy group reduced the number of drug-resistant S. aureus in the mammary glands by 8 log₁₀ CFU/g, while the antibiotic group reduced it by 4 log₁₀ CFU/g. Notably, the phage therapy group exhibited a more effective reduction in drug-resistant S. aureus compared to the antibiotic group. Additionally, the concentrations of tumor necrosis factor (TNF-α) and interleukin-6 (IL-6) in the treatment groups decreased significantly, especially in the phage treatment group. This indicates that phage treatment can more effectively reduce the inflammatory response in mouse mammary glands compared to ceftiofur sodium treatment. Similarly, Brouillette et al. (2023) formulated a phage cocktail called StaphLyse™, comprising five Myoviridae virulent S. aureus phages (SAML-4, SAML-12, SAML-150, SAML-229, and SATA-8505), which meet FDA safety standards for the treatment of mastitis in mice. StaphLyse™, at a concentration of 10⁹ PFU/mL, successfully lysed 709 strains of S. aureus, including MSSA, MRSA, and vancomycin-intermediate Staphylococcus aureus (VISA) strains, with a lysis rate of 100%. In in vitro experiments, StaphLyse™ (at approximately 10¹⁰ PFU/mL) reduced colony counts of S. aureus ATCC 29740 by 5.8 log₁₀ CFU/mL after 1 h. In a mouse infection model, researchers observed that administering StaphLyse™ intramammary (10⁸ PFU in 100 µL) at 8 and 16 h after infection was the most effective treatment regimen. This reduced the bacterial load per gram of mammary tissue by 2.82 log₁₀ CFU. In comparison, the amoxicillin control group (75 µg per gland, approximately 150 times the MIC of amoxicillin for S. aureus ATCC 29740) reduced the bacterial load per gram of mammary tissue by 4.45 log₁₀ CFU. Additionally, prophylactic use of StaphLyse™ (administered 4 h prior to infection) was also effective, reducing S. aureus levels by 4.03 log₁₀ CFU per gram of mammary gland. In another study, Kifelew et al. (2020) employed the phage cocktail AB-SA01 to treat multidrug-resistant S. aureus wound infections in diabetic mice. This cocktail was produced according to current good manufacturing practice (CGMP) standards and had undergone two phase I clinical trials (Lehman et al., 2019; Petrovic Fabijan et al., 2020). Results indicated that on the fourth day of treatment, the bacterial load in the phage treatment group and vancomycin treatment group had decreased by approximately 3.3 log₁₀ CFU/swab compared to the normal saline control group. On the third day after treatment, compared to the normal saline control group, the bacterial load in the phage treatment group and vancomycin treatment group had decreased by approximately 8 log₁₀ CFU/swab and 3.3 log₁₀ CFU/swab, respectively. Additionally, Laboratory et al. found that combining AB-SA01 with vancomycin exhibited a synergistic effect, enhancing the elimination of MRSA and preventing the development of phage resistance (Kebriaei et al., 2020b).

Different routes of administration also impact the therapeutic effectiveness of phages. In a mouse model infected with SA003, Fujiki et al. (2022) administered phage ΦSA012 (GenBank database accession number NC_023573.1) intraperitoneally and intravenously. This improved the survival rate of mice from 20% to 75% and 40%, respectively. Notably, ΦSA012 exhibited a broad-spectrum host range similar to Staphylococcus phage K, forming plaques in 94.4% (33/35) of animal-associated MRSA and MSSA strains and 60.0% (24/40) of human-associated MRSA strains. Furthermore, pharmacokinetic studies revealed that phage ΦSA012 was detected in the liver, lung, and intestine of mice without inducing any inflammatory reactions or potential side effects in the organs of mice.

However, as an active preparation, bacteriophages exhibit low stability and long-term effectiveness at the infection site (Guerin and Hill, 2020; Bichet et al., 2021), which somewhat limits their efficacy against infections. One strategy to protect bacteriophages from the influence of the adaptive immune system is encapsulating them in a carrier (Gembara and Dąbrowska, 2021; Wdowiak et al., 2022). Chhibber et al. (2018) employed liposomes as phage delivery vehicles to encapsulate a Myoviridae virulent S. aureus phage cocktail for treating MRSA-induced skin wound infections in diabetic mouse models. The results showed that 70% of mice in the blank control group died within 24 to 48 h after MRSA infection, and the bacterial loads at the wound increased to 9 log₁₀ CFU/mL. In contrast, no deaths occurred in the phage cocktail group (administered 100 µL at 10⁹ PFU/mL), clarithromycin group (administered at 10 mg/kg), or liposome-encapsulated phage cocktail group (administered 100 µL at 10⁹ PFU/mL). Over time, the bacterial loads in the treatment groups decreased, particularly in the liposome-encapsulated phage cocktail group. The bacterial loads decreased from 8.39 ± 0.72 log₁₀ CFU/mL to 1.84 ± 0.17 log₁₀ CFU/mL on the 7th day. The stability study of phages revealed that on the first day after administration, the phage cocktail titers in the wound of mice in the free phage cocktail treatment group and the liposome-encapsulated phage cocktail group decreased to approximately 10⁵ PFU/mL and 10⁷ PFU/mL, respectively. This indicates that liposome encapsulation can effectively prevent the decrease in bacteriophage activity and initial titer in the wound. It increases the time the bacteriophage functions at the infection site, thereby accelerating wound healing in mice.

Similarly, Onsea et al. (2021) treated rifampicin resistant S. aureus-induced fracture-related infections in a rabbit model by loading phages onto hydrogel. Initially, all animals in the treatment groups (Groups 3–5) received subcutaneous nafcillin (40 mg/kg, four times daily) and oral rifampicin (40 mg/kg, twice daily) for 7 days post-infection. Subsequently, Group 3 received phage injections (1 mL, 10⁸ PFU/mL in normal saline, twice daily), Group 4 underwent a single topical application of phage-loaded hydrogel (800 µL, 10⁹ PFU/mL), while Group 5 maintained the original antibiotic treatment. Results showed that infection was eradicated in 2 animals in Group 3, 1 animal in Group 4, and all animals in Group 5. Bacterial loads in the treatment groups decreased from 2 × 10⁶ CFU to approximately 10⁵ CFU. However, there was no statistically significant difference in bacterial loads between the treatment groups. Notably, the production of phage-neutralizing antibodies significantly impacts phage efficacy (Rotman et al., 2020). In this study, phage-neutralizing antibodies were only detected in the plasma of rabbits from Group 3, not in Group 4 or Group 5, suggesting that the hydrogel vehicle effectively reduces phage-neutralizing antibody production.

Additionally, Kalelkar et al. (2022) developed porous particles from degradable poly(lactic-co-glycolic acid) (PLGA) and successfully delivered a phage cocktail to the lungs of mice, effectively reducing MRSA-induced lung infections. Results indicated that compared to the control group of mice infected with MRSA, the bacterial loads in the porous particle vehicle group remained largely unchanged, indicating the vehicle had no antibacterial effect. The free phage cocktail group exhibited a reduction of approximately 1 log₁₀ CFU/mg, while the porous particle group loaded with the phage cocktail demonstrated the most significant effect, with a bacterial load reduction of approximately 2 log₁₀ CFU/mg. This suggests that PLGA vector synergistically enhanced the phage’s efficacy. Furthermore, the porous particle group loaded with the phage cocktail exhibited no significant toxicity to human lung epithelial cells, and the bacteria recovered from mice remained sensitive to the phage, with no emergence of phage antibodies. These findings underscore that the use of appropriate vehicles can enhance phage therapy’s effectiveness, reduce its biotoxicity, and mitigate drug resistance concerns.

In addition to laboratory investigations, several clinical cases have showed the promising potential of phage therapy against drug-resistant S. aureus infections. Ferry et al. (2020) notably improved the clinical condition of three patients with recurrent S. aureus clinical isolate (MSSA) prosthetic knee infections (PKIs) by employing a phage cocktail in conjunction with inhibitory antibiotics. Initially, all patients underwent “Debridement Antibiotics and Implant Retention” (DAIR) treatment and received a course of antibiotics, but these interventions proved ineffective, and the patients’ prosthetic knee joints remained severely infected. Consequently, hospital pharmacists formulated three phage cocktail preparations (PP1493, PP1815, and PP1957) at a final concentration of 10⁹ PFU/mL, which were subsequently injected directly into the joints post-DAIR surgery and joint closure. This treatment was followed by combined antibiotic therapy for 6 to 12 weeks, along with suppressive antibiotic treatment (SAT). After follow-ups at 7, 11, and 30 months, two patients exhibited only mild synovial fluid discharge and limited synovial inflammation, with no persistent or recurrent bacterial infections. Moreover, their C-reactive protein levels were negative, and clinical symptoms, such as pain-free ambulation, significantly improved. Similarly, in another clinical case involving S. aureus PKI infection, Ramirez-Sanchez et al. (2021) successfully cured a 61-year-old female patient using sequential intra-articular infusions of phage cocktail AB-SA01 and a single lytic phage, SaGR51ø1. Initially, after several courses of intravenous cefazolin injections, oral rifampicin and amoxicillin administration, the patient’s knee joint infection persisted. Phage therapy was then attempted, beginning with intravenous infusions of phage cocktail AB-SA01 (once every 12 h for 2 weeks) and cefazolin (once every 8 h for 6 weeks). During this treatment, bacterial cultures from the patient’s blood and synovial fluid returned negative results, and her pain subsided. However, the unavailability of further phage cocktail AB-SA01 products led to the cessation of phage therapy after two weeks, resulting in knee pain recurrence and positive S. aureus clinical isolate (MSSA) cultures five days later. Subsequently, during the second treatment cycle, 10 mL of phage solution SaGR51ø1 (2.89 × 10¹⁰ PFU/mL) was aseptically injected into the joint cavity (once every 12 h for 6 weeks), accompanied by intravenous cefazolin administration (once every 8 h for 6 weeks). After completing both treatment cycles, the patient’s synovial fluid exhibited no inflammation, bacterial cultures returned negative results, and no adverse events associated with phage therapy were reported. These findings suggest that virulent phage SaGR51ø1 exhibits a favorable safety and efficacy profile against S. aureus PKI infections. Furthermore, phage therapy has demonstrated efficacy and safety against PKI infections caused by MRSA (B. et al., 2022; Schoeffel et al., 2022), as seen in similar clinical cases.

As mentioned earlier, an increasing number of prominent and extensively documented clinical case reports, along with the improved accessibility of phage identification and production technologies, have contributed to the expanded adoption of phages in clinical medicine during recent years (Strathdee et al., 2023). In a single-arm, non-comparative clinical trial, an Australian hospital assessed the safety of S. aureus phage in humans by administering phage cocktail AB-SA01 as adjuvant therapy to 13 critically ill patients with S. aureus bacteremia (Petrovic Fabijan et al., 2020). All patients initially received antibiotics such as flucloxacillin (n = 10), cefazolin (n = 2), or vancomycin (n = 1), supplemented with ciprofloxacin and/or rifampicin, followed by intravenous administration of phage cocktail AB-SA01 between 4 and 10 days after antibiotic treatment initiation. Results revealed that after 90 days of phage therapy, seven patients (54%) displayed clinical improvement and survived, while six patients (46%) succumbed, including three within one week. During AB-SA01 infusion and the 4-h period thereafter, no adverse reactions such as fever, rash, or hypotension were observed. Moreover, no serious inflammatory reactions were reported in patients, signifying the safety and tolerability of AB-SA01 via intravenous administration against S. aureus clinical isolate (MRSA and MSSA). However, further controlled trials are needed to determine AB-SA01’s efficacy. In addition, Ooi et al. (2019) demonstrated the safety and tolerability of multiple intranasal administrations of AB-SA01 in patients with recalcitrant chronic rhinosinusitis caused by S. aureus clinical isolate. This study is a phase I clinical trial involving multiple ascending doses, conducted in humans for the first time. It is a single-center, prospective, and open-label trial. The trial has been registered at http://anzctr.org.au, with the identifier ACTRN12616000002482. Nine patients have been enrolled in the trial, and they are divided into three cohorts, with each cohort consisting of three patients. Each cohort received intranasal irrigation with AB-SA01 twice daily, following an ascending dose scheme: 3 × 10⁸ PFU for 7 days (cohort 1), 3 × 10⁸ PFU for 14 days (cohort 2), and 3 × 10⁹ PFU for 14 days (cohort 3). Results indicated that all participants’ vital signs, including body temperature and blood pressure, as well as clinical biochemical parameters such as hemoglobin and platelet levels, remained within normal ranges before administration, 0.5 h and 2.0 h post-AB-SA01 administration, and at the exit visit. No serious adverse events were reported, underscoring the safety and tolerability of AB-SA01. Furthermore, S. aureus infection diminished in all patients, with eradication achieved in two patients, suggesting promising preliminary efficacy results. However, due to the small sample size, further randomized clinical trials are necessary to confirm AB-SA01’s efficacy.

Subsequently, Leitner et al. (2021) conducted a randomized, placebo-controlled, double-blind clinical trial (Identifier, NCT03140085) to treat urinary tract infections (UTIs) in patients undergoing transurethral resection of the prostate (TURP) using intravesical phage cocktail Pyophage. Among 474 screened patients, 113 with positive urine S. aureus cultures entered the study (including Staphylococcus spp., Streptococcus spp., Enterococcus spp., and Escherichia coli, with colony counts ≥10⁴ CFU/mL). Patients were randomly assigned to receive treatment, resulting in 97 patients receiving one of three interventions: the phage group (n = 28), the placebo group (n = 32), or the antibiotic group (n = 37). Post-treatment assessments revealed no statistically significant differences in success rates or adverse event incidence among the three groups. Notably, intravesical phage therapy’s efficacy in treating Staphylococcus-induced UTIs was comparable to that of antibiotic treatment, but it did not outperform the placebo control group. This outcome may be attributed to bladder irrigation, which unexpectedly reduced bacterial loads in all groups. This randomized double-blind clinical trial reiterated phage therapy’s safety and tolerance while encouraging larger, high-quality clinical investigations.

In 1958, Jacob et al. made the pioneering discovery that bacteriophages can encode a class of proteins exhibiting the capacity to lyse bacteria. These proteins, termed endolysins or lysins, serve a crucial role in the bacteriophage infection process by lysing the host bacteria. Lysins are cell wall hydrolases synthesized by phage genes during the late stages of dsDNA phage infection in bacteria. In the bacteriophage lysis replication cycle, lysins pass through cell membrane pores formed by holin and subsequently target the peptidoglycan within the bacterial cell wall. They cleave and hydrolyze vital chemical bonds in the peptidoglycan, ultimately leading to bacterial lysis and demise. This process facilitates the release of progeny phages into the extracellular environment (Abdelrahman et al., 2021).

While complete phages remain a viable antibacterial option, their limited antibacterial spectrum, intricate preclinical and clinical evaluations, and inadequate regulatory frameworks have impeded the widespread adoption of phage therapy (Abdelkader et al., 2019; Rahman et al., 2021). In contrast, lysin development has progressed more rapidly. Lysins offer advantages such as non-proliferation, high bactericidal activity, a broad host spectrum, well-defined pharmacokinetics, reduced likelihood of developing resistance, and antibodies that do not significantly diminish bactericidal activity. Consequently, lysins have emerged as significant candidates for antibiotic alternatives (Kortright et al., 2019; Röhrig et al., 2020; Abdelrahman et al., 2021; Lu et al., 2021; Murray et al., 2021; Hatfull et al., 2022; Zhu et al., 2022).

In 1959, Freimer et al. successfully purified lysins with bactericidal properties. In 2001, phage lysins were first employed as local antibacterial agents. The presence of the outer membrane in Gram-negative bacteria poses a physical barrier to lysins, impacting their effectiveness. In contrast, lysins can directly target peptidoglycan bonds and lyse the cell walls of Gram-positive bacteria, making lysins particularly effective against infections caused by Gram-positive bacteria (Abdelrahman et al., 2021; Murray et al., 2021). As a result, extensive research has focused on combating Gram-positive bacteria, especially drug-resistant S. aureus, with lysins. For example, lysin LysP108 exhibited up to 90% antimicrobial activity against MRSA and hindered bacterial biofilm formation (Lu et al., 2021). The catalytic domain of lysin CHAP LysGH15 reduced S. aureus levels in milk by approximately 2.5 log₁₀ CFU/mL after 8 h at 4°C (Yan et al., 2021). Chimeric lysin ClyC decreased MRSA suspensions in vitro and in mice by 9 log₁₀ CFU/mL and 2 log₁₀ CFU/mL, respectively, and exhibited synergy with penicillin (Li X. et al., 2021). Recombinant lysin XZ.700 inhibited S. aureus clinical isolate proliferation and skin colonization (Pallesen et al., 2023).

Furthermore, lysins are susceptible to degradation by gastric acid and proteases upon entering the body, posing a considerable obstacle to lysin therapy’s application. Encapsulation technology offers an effective means of protecting lysins (Haddad Kashani et al., 2017; Gondil and Chhibber, 2021; Murray et al., 2021). Portilla et al. (2020) encapsulated LysRODI in pH-sensitive liposomes, which reduced S. aureus clinical isolate suspensions in weakly acidic (pH 5) environments and S. aureus within biofilms by 2 log₁₀ CFU/mL. Yao et al. (2021) encapsulated chimeric lysin ClyC in alginate hydrogel, preserving ClyC’s stability while reducing cytotoxicity resulting from high concentrations (250 µg/mL) of ClyC in local infections. The researchers found that the cumulative release of ClyC from ClyC-alginate hydrogel in Tris buffer at 37°C after 72 h was approximately 23 ± 0.45%, and ClyC maintained its structural integrity without hydrolysis or degradation during gelation and release. ClyC-alginate hydrogel demonstrated almost zero cytotoxicity when incubated with BHK-21 cells, compared to 80% relative cytotoxicity for 250 µg/mL free ClyC after 24 h. In a mouse model of S. aureus T23-induced osteomyelitis, ClyC-alginate hydrogel reduced bacterial loads in the femur and surrounding tissues by 2 log₁₀ CFU/mL, showing efficacy equivalent to that of free ClyC. However, this study warrants longer experimentation periods to assess its effects on bone healing and local inflammation adequately. Additionally, Kaur et al. observed increased bactericidal activity when delivering LysMR-5 via alginate-chitosan nanoparticles (Alg-Chi NPs) (Kaur et al., 2020). Results indicated that after 4 h of incubation at 37°C, the bacterial loads reduced to 10⁶ CFU/mL with blank Alg-Chi NPs (500 µg/mL), 10⁴ CFU/mL with free LysMR-5 (155 µg/mL), and 10³ CFU/mL with LysMR-5-loaded Alg-Chi NPs (500 µg/mL), compared to the initial bacterial loads of 10⁸ CFU/mL.

In 2013, Micreos introduced Gladskin (also known as Lysin SA.100 or Staphefeckt SA.100), the world’s first phage lysin product. It is primarily used as an adjuvant treatment for inflammatory skin diseases caused by MRSA (Totté et al., 2017). Staphefekt is currently registered as a (class 1) medical device in Europe, available in polycestol cream and over-the-counter gel forms. In vitro studies demonstrated that Staphefekt specifically targeted MSSA and MRSA, without affecting other commensal skin bacteria and without inducing drug resistance (Pastagia et al., 2013). In three case reports, local treatment with Staphefekt SA.100 inhibited drug-resistant S. aureus, effectively curing chronic recurrent S. aureus-related skin diseases that were previously resistant to antibiotics like clarithromycin, flucloxacillin, and fusidic acid cream during the early stages of treatment (Totté et al., 2017). While this study highlights Staphefekt’s potential as an alternative to conventional antibiotics for treating drug-resistant S. aureus-related skin infections, its efficacy and safety require further investigation through randomized controlled clinical trials.

Subsequently, in a multi-center, placebo-controlled, double-blinded, and randomized superiority trial (Home | ClinicalTrials.gov; Identifier, NCT02840955), 100 patients with moderate to severe atopic dermatitis received 12 weeks of Staphefekt treatment. Results indicated that short-term application of Staphefekt did not significantly impact non-infectious specific dermatitis patients. Simultaneous application of topical corticosteroids (TCS) and emollients may have masked any clinical benefits. However, the trial demonstrated that Staphefekt was safe and well tolerated (Totté J. et al., 2017; de Wit et al., 2019).

Gangagen, an Indian company, has developed an engineered lysin called P128 to combat S. aureus infections in the nasal cavity, especially MRSA infection. They have successfully completed a phase IIa clinical trial (ClinicalTrials.gov; Identifier: NCT01746654). Additionally, SAL200, another endolysin candidate for treating SaB, is currently undergoing a phase IIa clinical trial (Jun et al., 2017; Abdelkader et al., 2019; Indiani et al., 2019). Furthermore, Exebacase, a lysin designed for targeting MRSA (also known as CF-301 or PlySs2), has completed phase II clinical trials in humans (ClinicalTrials.gov; Identifier: NCT03163446). These trials have demonstrated the safety and efficacy of lysin and its synergistic effects when combined with antibiotics (Fowler et al., 2020). Currently, Exebacase is being investigated in experimental treatments for MRSA bacteremia and endocarditis patients in phase III clinical trials (ClinicalTrials.gov; Identifier: NCT04160468). If successful, it will become the first lysin-based drug (Traczewski Maria et al., 2021).