Coronary chronic total occlusion (CTO) percutaneous coronary intervention (PCI) remains a cornerstone in revascularization strategies, with contemporary studies demonstrating improved procedural success rates exceeding 90% in experienced centers (1). However, long-term outcomes remain concerning, as 40–55% of patients develop coronary microvascular dysfunction (CMVD) post-PCI, significantly increasing risks of recurrent ischemia and major adverse cardiovascular events (MACE). According to a meta-analysis’s subgroup analysis, 36.04% of patients with chronic coronary syndrome (CCS) experience CMVD following PCI (2). About 17.86% of patients with CCS had CTO (3). Numerous studies have established a strong link between CMVD and an increased risk of cardiovascular events (4). For example, in patients with ST-segment elevation myocardial infarction (STEMI), CMVD is common and is closely associated with left ventricular diastolic dysfunction, functional left ventricular remodeling (FLVR), and MACE (5). In obese patients, CMVD not only correlates with an elevated risk of adverse cardiovascular events but also serves as a more robust predictor than body mass index (BMI) (6). This disparity between high procedural success and suboptimal long-term outcomes presents an acute clinical challenge. Although we are proficient in reopening occluded epicardial arteries, protecting the fragile microvasculature from ischemia–reperfusion injury remains a significant hurdle. Addressing this challenge requires further exploration of diagnostic and therapeutic approaches to manage patients at high risk of CMVD-related complications.

Shexiang Baoxin pill (SBP), a representative formulation of traditional Chinese medicine, demonstrates its therapeutic efficacy through the synergistic action of multiple constituents. Artificial musk improves blood circulation and reduces myocardial ischemia. Ginseng boosts qi, modulates the immune system, and supports heart function. Suhexiang aids qi circulation and pain relief, helping alleviate angina symptoms. Calculus Bovis, Bufonis Venenum, and Cinnamomi Cortex clear heat and detoxify, while Borneolum Syntheticum enhances delivery of all components. Recent pharmacological research has substantiated that SBP facilitates the release of nitric oxide by vascular endothelial cells, leading to the dilation of coronary arteries and an increase in coronary blood flow (7). It also inhibits inflammatory cytokines, thereby reducing vascular wall inflammation and stabilizing atherosclerotic plaques. Additionally, the pill promotes angiogenesis, establishing collateral circulation for ischemic myocardium and enhancing myocardial blood supply (8). By improving vascular endothelial function, it aids in the release of vasodilatory substances such as nitric oxide, thereby enhancing blood flow (9). Furthermore, it suppresses vascular wall inflammation by reducing the infiltration of inflammatory cells and the release of harmful mediators, thus slowing the progression of atherosclerosis (10). The pill also encourages therapeutic angiogenesis, stimulating the growth of new blood vessels to support the ischemic myocardium. Its active components, including muscone and ginsenosides, enhance endothelial nitric oxide synthase (eNOS) coupling, reduce nod-like receptor pyrin domain containing 3 (NLRP3) inflammasome activation, and promote VEGF-mediated angiogenesis (11, 12).

Exercise rehabilitation is crucial for managing coronary heart disease by improving coronary artery collateral circulation and microcirculation (13). Regular physical activity strengthens alternative blood flow pathways and enhances oxygen and nutrient delivery to the heart muscle (14). Furthermore, structured exercise rehabilitation has been shown to confer significant microcirculatory benefits through mechanisms such as shear stress-mediated endothelial repair and the activation of the hypoxia-inducible factor 1α (HIF-1α) pathway (15). A meta-analysis of multiple randomized controlled trials has demonstrated that exercise rehabilitation reduces the risk of major cardiovascular events, such as heart attacks and strokes, by 28% in patients with coronary heart disease (16–18). Another study assessed the comparative benefits of cardiac rehabilitation strategies through a Bayesian network meta-analysis, revealing that exercise-only cardiac rehabilitation was associated with decreased cardiovascular mortality and major adverse cardiovascular events (19). Despite these advancements, there is limited research on combining SBP and exercise rehabilitation for those undergoing CTO-PCI. The 2023 ESC guidelines recommend microvascular protection but do not provide specific protocols for integrative approaches. This gap in knowledge hinders the personalized management of high-risk CMVD patients.

The combined use of SBP and exercise rehabilitation offers synergistic benefits, particularly in improving myocardial blood supply. SBP promotes angiogenesis, increasing coronary microvessel number and diameter, while exercise rehabilitation enhances collateral circulation, boosting blood perfusion efficiency in both new and existing microvessels. This integrated approach is more effective in mitigating myocardial ischemia. We suggest that synchronizing SBP with exercise rehabilitation enhances therapeutic outcomes through three aspects: (1) improved coronary microcirculatory function; (2) reduced major adverse cardiovascular events within a year; and (3) enhanced patient quality of life. This study introduces an integrative model for post-PCI microvascular rehabilitation, merging traditional Chinese medicine’s systemic regulation with Western exercise physiology’s biomechanical precision, marking a shift from fragmented approaches. Successful validation could reshape international guidelines, providing the first Class I recommendation for combined pharmaco-mechanical CMVD management.

As recommended in clinical guidelines, the core population indicated for CTO-PCI consists of patients with refractory angina despite optimal medical therapy, or those with extensive myocardial ischemia in the occluded territory (21). These subgroups are more likely to derive substantial survival benefits from the procedure. To optimize the selection of surgical strategies, clinicians often evaluate the characteristics of occluded vessels using the Japanese Chronic Total Occlusion Score (J-CTO) system (22). This scoring system includes four coronary angiography (CAG) indicators: blunt stump, calcification, intralesional bend >45°, and occlusion length ≥20 mm. In addition, the diameter of the occluded vessel is also one of the key factors influencing the success rate of the procedure. The antegrade wiring (AW) technique serves as the most commonly used foundational approach in CTO-PCI, while supplementary techniques such as antegrade dissection reentry (ADR), retrograde wiring (RW), and retrograde dissection reentry (RDR) are often employed as adjunctive methods (23, 24). These complementary strategies aim to maximize the success rate and safety of the procedure.

Patients undergoing CTO-PCI frequently have decreased intravascular pressure and coronary blood flow after the surgery; this causes the blocked vessel to appear to have a negative remodeling change, concurrently causing modifications in distal myocardial microvascular structure and function. These adverse changes interact to ultimately trigger CMVD, seriously impacting the long-term prognosis of patients (25). Consequently, accurate evaluation of coronary microvascular function, it is critical for early diagnosis of cardiovascular diseases, optimization of treatment strategies, and prediction of cardiovascular event risk. Cardiovascular magnetic resonance (CMR) imaging, covering coronary flow reserve (CFR) and index of microcirculatory resistance (IMR), widely accepted as a CMVD diagnostic criterion, is a highly promising non-invasive imaging modality of choice (26). Nevertheless, it does not display the real-time dynamic process of myocardial perfusion, and there are strict criteria for inspection equipment, so it might be challenging to perform bedside examinations on individuals who are very sick and immobile. Additionally, despite the fact that CMR can evaluate coronary microvascular function, when it comes to presenting outcomes, it lacks sensitivity and intuition. In this study, myocardial contrast echocardiography (MCE) and stress myocardial perfusion imaging (MPI) will be used as the primary outcomes to assess microvascular improvement. In recent years, these two technologies have gained prominence. Compared with conventional imaging, it provides a data-driven demonstration of myocardial blood perfusion; it also enables a more intuitive assessment of myocardial microcirculatory perfusion status, to provide a fresh method to quantify the functional state of the microvasculature accurately (27–29). Additionally, they have a close association with common outcomes like MACE; it offers a crucial basis for risk prediction and prognostic evaluation of cardiovascular disease (30). By using these technologies, physicians will formulate more accurate treatment plans to advance in cardiovascular disease diagnosis and therapy.

Shexiang Baoxin pill, as a TCM formulation, has been studied for its effects on CMVD. They may act through multiple mechanisms such as promoting angiogenesis, improving endothelial function, and reducing inflammation. SBP has a long-standing history in the treatment of cardiovascular diseases. Derived from traditional Chinese medicine, it has been broadly applied in East Asia for decades to treat conditions like coronary heart disease, heart failure, and hypertension (31). Clinically, a multicenter, double-blind, placebo-controlled phase IV randomized clinical trial involving 2,674 patients with stable coronary artery disease found that SBP, as an add-on to optimal medical therapy, was safe and significantly reduced angina frequency, with a trend toward reduced major adverse cardiovascular events (32). Additionally, clinical practice has shown that combination therapy has a synergistic effect. In the study of heart failure patients with preserved ejection fraction, 60 patients were randomly divided into three groups: group A received SBP combined with home-based exercise training, group B received conventional drugs combined with home-based exercise training, and group C received conventional drug treatment only. After the 12-week intervention, both groups A and B showed significant improvements in peak oxygen uptake, anaerobic threshold, 6-min walking test, Pittsburgh Sleep Quality Index, and SF-36 questionnaire results compared with pre-treatment (p < 0.01). Moreover, the improvement degree of group A in some indicators was superior to that of group B, which further demonstrated the positive impact of the combined treatment of SBP and exercise on the patients’ condition (33). These studies have gradually elucidated the role of SBP in cardiovascular diseases and laid the foundation for its clinical application.

In this study, considering the requirements of the patient’s physical condition and long-term compliance, etc., according to the latest cardiac rehabilitation guidelines, exercise rehabilitation is divided into two parts: indoor and outdoor (34). Outdoor exercise using brisk walking: this approach is simple and easy; it has been shown to have a beneficial effect on the rehabilitation of elderly cardiac patients (35). Indoor exercise with Baduanjin, as a low-to-medium-intensity aerobic exercise, because of its site independence and cost-effectiveness, is suitable as a long-term rehabilitation program for our study. Moreover, we will grade patients’ activity intensity based on CPET (36). Based on baseline conditions like the patient’s level of living and the complexity of the disease, etc., develop individualized exercise programs and implement the full-spatial rehabilitation cycle. In-hospital, post-discharge outpatient, and long-term out-of-hospital three-phase, accurately match the frequency and timing of exercises. Following the principle of tertiary rehabilitation in the full cycle of the disease, improve the quality of rehabilitation progressively. In addition, this study followed an approach of the full cycle of participants, a rehabilitation team consisting of cardiologists, rehabilitation therapists, specialized cardiothoracic nurses, carers of patients, etc., supporting patients in multiple dimensions, to ensure the effectiveness of long-term interventions (Figure 3 for details). Exercise rehabilitation is defined by the European Heart Association and the American Heart Association as a class IA treatment for coronary artery disease (37), with high treatment efficacy and cost-effectiveness for improving long-term prognosis (38). The study shows, regular exercise reduces the risk of all-cause mortality by 52%, and the risk of major adverse cardiovascular events by 41% (39).

SBP and exercise rehabilitation interact across multiple physiological action pathways; they all exert positive effects on cardiac function, vascular endothelial function, and hemodynamics. Pharmacokinetic aspects: low-to-moderate-intensity exercise enhances whole-body metabolic status, making the environment conducive to drug metabolism. Particularly in the digestive system, compared to intense exercise, low- to moderate-intensity exercise is beneficial for drug absorption; it allows for faster efficacy and a better degree of absorption (40). Moreover, long-term exercise training also increases the activity of liver enzymes, such as cytochrome P450, which break down medications, lowering the risk of drug buildup in the body (41). The study noted that co-administration of these has a significant impact on enhancing cardiac function and improving the quality of life in patients with cardiovascular diseases (33).

This study has the following advantages: in study design, strict adherence to evidence-based medical norms. The generation of random sequences by computer, and complete distribution concealment with opaque envelope seals, raises the credibility of the study findings. In addition to the primary outcome, the Seattle Angina Questionnaire (SAQ) will also be used to evaluate the quality of life of the patients, to comprehensively reflect the impact of the treatment, on the overall state of the patient from the patient’s subjective feelings, to provide a more thorough viewpoint for evaluating the treatment effect. In addition to routine clinical outcomes, this study will also gather multidimensional data on inflammatory factors, angiogenesis-related and exercise-related factors, digging into the mechanism in detail at the molecular level. Nevertheless, this study also has some limitations. The study was conducted in only one tertiary A hospital; all subjects were recruited from a single source, which may affect the stability and extrapolation of the findings. Moreover, data collection during the trial was made more challenging by the 1-year follow-up period and possible high dropout rate, which will make the study less effective.

In previous cardiac rehabilitation studies, CTO-PCI patients were often overlooked, and it has a high incidence of microvascular dysfunction after surgery and a poor prognosis (4). This study abandons the single-therapy approach of the previous one, using the combined drug and exercise treatment strategies; the aim was to investigate the effect of SBP combined with exercise rehabilitation training on the long-term prognosis of CTO-PCI patients.

After the trial ends, the results will be published in a Chinese or English journal to ensure wide dissemination.

This protocol presents a methodologically robust and innovative approach to addressing post-CTO-PCI microvascular dysfunction through integrative medicine. By combining SBP’s multi-target pharmacology with precision-guided exercise rehabilitation, the study aims to establish a new paradigm for microvascular protection. Its findings may catalyze future research on synergistic therapies and inform global guidelines for high-risk coronary artery disease populations.