Journal of Contemporary Brachytherapy
eISSN: 2081-2841
ISSN: 1689-832X
Journal of Contemporary Brachytherapy
Current Issue Archive Supplements Articles in Press Journal Information Aims and Scope Editorial Office Editorial Board Register as Author Register as Reviewer Instructions for Authors Abstracting and indexing Subscription Advertising Information Links
Editorial System
Submit your Manuscript
SCImago Journal & Country Rank
Search
6/2025
vol. 17
 
Share:
Send email
Share:
Original paper

Percutaneous coronary intervention followed by intravascular brachytherapy for management of drug-eluting stents in-stent restenosis in patients with complex coronary artery lesions

Mark Trombetta
1, 2
,
Hirsch Matani
1
,
Hardik A. Valand
3
,
Siddharth B. Reddy
4
,
Triston B. Smith
5
,
Daniel Pavord
1
,
David Lasorda
2, 3

  1. Division of Radiation Oncology, Allegheny General Hospital, Pittsburgh, PA 15212, USA
  2. Drexel University College of Medicine, Pittsburgh Campus, Pittsburgh, PA 15212, USA
  3. Division of Interventional Cardiology, Allegheny General Hospital, Pittsburgh, PA 15212, USA
  4. Baptist Memorial Hospital, Columbus, MS 39705, USA
  5. Division of Cardiology, Trinity Health System, Steubenville, OH 43952, USA
J Contemp Brachytherapy 2025; 17, 6: 355–361
DOI: https://doi.org/10.5114/jcb.2025.158502
Online publish date: 2025/12/31
Article file
- Percutaneous coronary intervention.pdf  [0.21 MB]
Get citation
 
 

Purpose

Coronary artery disease (CAD) is a condition that occurs when blood flow to the myocardium is reduced usually due to atherosclerotic plaque changes in the lumen of coronary vessels [1]. These plaques can remain stable or progressively narrow the vessel’s lumen, reducing the blood flow to the myocardium and leading to angina-like symptoms. Alternatively, some plaques may rupture and cause thrombosis, resulting in sub-total or total occlusion of distal coronary vessels, which can manifest in a spectrum of acute coronary syndromes (ACS), such as unstable angina, non-ST elevation myocardial infarction (NSTEMI), or ST elevation myocardial infarction (STEMI) [1]. In the United States, approximately 20.1 million adults aged above 20 years have CAD, constituting approximately 7.2% of the general population. Coronary artery disease is the leading cause of mortality, accounting for approximately 20% of all deaths in the United States, and being responsible for 610,000 deaths annually [2-4]. The management of symptomatic ACS is largely accomplished via pharmacotherapy and percutaneous coronary intervention (PCI), using coronary stents to restore the vascular flow. Stenting has been a major advancement in treatment, with over 600,000 stents deployed annually [5]. Among various coronary stents, bare metal stents (BMS) and drug-eluting stents (DES) are the two most popular options. Active antiproliferative pharmacological agents, such as paclitaxel and sirolimus as the active agents for DES, exhibit anti-inflammatory and antiproliferative properties, thereby suppressing neointimal hyperplasia [6]. This results in decreased ISR rate by 50-70% in comparison with BMS, showing improved clinical outcomes in patients undergoing PCI [6, 9-11]. Coronary stents reduce the risk of restenosis by offering a mechanical scaffolding, which physically reduces coronary vascular contraction but, both BMS and DES, induce greater neointimal growth causing ISR [7-13].

In-stent restenosis and stent-in-stent restenosis

In-stent restenosis is defined as a new proliferative re-narrowing of the previously stented lesion that encompass either the stent segment or a 5 mm segment on both sides of the stent, with these lesions affecting at least 50% of the lumen diameter per coronary angiography [14-16]. Once ISR occurs, cardiologists have several management options to perform, including balloon angioplasty, drug-coated balloon (DCB) angioplasty, cutting balloon angioplasty, and the potential use of atherectomy devices. Most of the time, IRS is managed with repeat DES placement [17-20].

With the rapid adoption of DES in routine practice and increasing number of patients requiring PCIs and stenting, the incidence of ISR has also been on the rise, developing a new challenge, i.e., the occurrence of DES-IRS or stent-in-stent restenosis (SISR). These are described as having ≥ 2 previous episodes of ISR, and their management is extremely challenging due to narrowing of the vessel’s lumen from multiple stent layers [21, 22]. Compared with BMS, DES-ISR rates are reported to be < 10%, but are higher in medically complex patients [14]. In low-risk individuals, the restenosis rate is approximately 12-14% [15-17]. A discernable escalation is noted in ≥ 3 stent layers, resulting in an increase in the rate of repeat failure to 41% within one year [23-25]. One option for the management includes implantation of a DCB, primarily utilized in Europe. Recommendations in the United States are less clear, and guidelines do not address treatment options for multi-layered stent restenosis [26-28].

Intravascular brachytherapy (IVBT) was originally approved for the treatment of BMS-related ISR more than 25 years ago, with patency ranging from 60-87% [13, 29-31]. However, due to the efficacy of DES, brachytherapy use decreased significantly [32]. Currently, IVBT provides an alternative to achieve revascularization in patients with multi-layered DES. The utility of IVBT lies in the decreasing rate of major adverse cardiac events [33], and it is especially attractive alternative for patients who have complex lesion(s) with recurrent ISR, and are poor candidates to receive another DES or bypass surgery [34, 35]. This study reported the outcomes and complications of a large registry of patients, who have received IVBT for DES-ISR at a single-institution.

Material and methods

Study population

An analysis of 78 patients involving 91 vessels treated from 2017-2024 was performed. Patients with DES-ISR received IVBT therapy using the Novoste Beta-Cath® system (Atlanta, Ga, USA) post-PCI with balloon angioplasty. Inclusion criteria encompassed patients with ISR, specifically those with recurrent episodes (> 2 stent layers), defined as SISR or DES-ISR. The presence of two layers of stents contributed to the classification of lesions as complex. The decision to utilize IVBT was at discretion of the treating interventional cardiologist and radiation oncologist. Patients were selected for IVBT under the following criteria: 1. At least two layers of stents were required to have been previously deployed, with no further stenting possible; 2. Patients who failed at least one angioplasty with resultant re-occlusion prior to IVBT; 3. Patients with limited options for revascularization as per the attending interventionalist, referring interventionalist, and radiation oncologist.

Brachytherapy was delivered with the Beta-Cath® system using a strontium-90 (90Sr) isotope, following balloon angioplasty. Radiation dose delivered was 23 Gy to vessels of ≥ 3.5 mm in diameter, while 18.4 Gy was delivered to vessels of < 3.5 mm in diameter, according to the manufacturer. Radiation was prescribed to an area encompassing the angioplasty injury length, with a 10 mm longitudinal margin on each side. Source length was 60 mm, and dwell times were variable depending upon the source activity and vessel lumen size (range, 455-603 seconds).

Post-PCI, a delivery catheter with a radiopaque maker was advanced and localized under fluoroscopy using the B-rail® (Novoste; Best Vascular, Norcross, Ga, USA) delivery catheter. After obtaining appropriate positioning, the delivery Beta-Cath® device was attached, and the source was sent via hydraulic pressure in a self-contained system. Two manual timers were initiated when the source reached the target location. After the planned dwell time was reached, the source was hydraulically retracted, and the catheter was removed once the source was identified as contained in the delivery device. A patient and general room survey was performed post-procedure, ensuring the isotope was returned completely to the delivery system. Major adverse cardiac events (MACE) were defined as myocardial infarction (MI), stroke, and all-cause death. Data collection was carried out independently by two investigators, and reviewed by two additional investigators.

Results

The median patient age was 67 years, and baseline demographics and relevant medical histories were recorded for all patients (Table 1). All patients had at least 2 drug-eluting stents previously placed in the affected vessel. Sixty-one treatments were delivered to the left anterior descending artery (LAD) or the right coronary artery (RCA), with the remaining 30 delivered to either the circumflex vessel or marginal artery (Table 2). Sixty-three percent received 23 Gy, while 37% received 18.4 Gy. One patient experienced cardiac arrest from suspected intracoronary thrombosis during receiving the intervention and died despite aggressive resuscitation, including extra-corporeal oxygenation. No other procedure-related toxicities were reported. All patients were symptomatic before IVBT, and 44% experienced symptomatic reduction during follow-up. The most common persistent symptom was angina in 71% of cases. The major adverse cardiovascular events after IVBT included MI in 18%, stroke in 5%, and all-cause death occurring in 16% at a median time of 9.3 months after treatment (range, 0.9-29.6 months) (Table 3). At a median follow-up of 22.8 months (range, 0.9-60.6 months), 77% of patients retained luminal patency of the irradiated lesion, while 23% experienced restenosis.

Table 1

Baseline characteristics and other comorbidities

CharacteristicsMedianIQR
Age (years)6759-75.5
Vessel diameter (mm)3.53-3.5
Segment number1
Injury length (mm)3521.5-50
Dose (Gy)2318.4-23

[i] IQR – interquartile range

Table 2

Vessels treated

Vessel treatedNumber of lesions (%)
LAD32 (35)
RCA29 (32)
LCX23 (25)
OM7 (8)

[i] LAD – left anterior descending, RCA – right coronary artery, LCX – left circumflex artery, OM – obtuse marginal

Table 3

Major adverse events

MACE eventsNumber of events (%)Median latency (days)
Myocardial infarction16 (18)337 (222-732)
Stroke/TIA5 (5)463 (439-802)
All-cause mortality15 (16)279 (222-563)

[i] MACE – major adverse cardiac events, TIA – transient ischemic attack

Discussion

In this study, we investigated the safety and efficacy of IVBT in patients with complex lesions experiencing reoccurring DES-ISR. This approach resulted in an acceptable 1-year MACE rate while retaining symptomatic patency of the irradiated lesion in 77% of patients, who would otherwise have minimal therapeutic options. We also found that this approach provided symptomatic improvement in many patients, potentially enhancing quality of life of those with reoccurring DES-ISR.

In-stent restenosis pathogenesis in BMS and DES

Bare metal stents are comprised of stainless-steel, cobalt chromium, or platinum chromium, with a higher incidence of ISR than DES and peak incidence of restenosis occurring at approximately 6 months post-implantation [32, 36, 37]. In BMS, ISR is mainly secondary to smooth muscle hypertrophy and aggressive neointimal hyperplasia [38]. In contrast, DES is composed of stainless steel or cobalt-chromium metal, and contains an active pharmacologic drug, making it more effective in preventing restenosis and reducing stent thrombosis[39]. For DES, neointimal hyperplasia and neoatherosclerosis are the key mechanisms behind DES-ISR [40-42]. ISR post-DES placement can be attributed to various factors, including drug resistance due to the coated polymer (e.g., sirolimus or paclitaxel) on the scaffolding of DES, hypersensitivity reactions to the framework material (e.g., stainless steel and other alloys), under-expanded DES, stent fracture post-DES deployment, stent gaps, uncovered atherosclerotic plaque, and barotrauma outside the stented segment [14]. Additionally, intravascular ultrasound studies have shown that BMS-ISR follow diffuse pattern of stenosis, whereas DES involves stent edges [43].

Importantly, we noted generalized stent under deployment in almost all patients. Once DES-ISR occurs, cardiologists have limited strategies available, with repeated DES placement being the most selected approach in the United States (US) [17-20].

Management of DES-ISR

Intravascular brachytherapy interrupts the cell cycle by inhibiting neointimal proliferation in adventitial fibro-myoblasts inducing apoptosis [44]. IVBT involves the administration of radioactive beta radiation, leading to the disturbance of both single- and double-stranded DNA in rapidly dividing cells [45]. In our study, we utilized 90Sr, a pure beta particle emitter with energies up to 0.546 MeV and radioactive half-life of 28.79 years.

IVBT in the management of DES-ISR: Pre-DES and post-DES time

Eight years after the implantation of the first coronary stent in 1986, large cohort studies have demonstrated the superiority of BMS over standard balloon angioplasty in both angiographic and clinical events among patients with CAD [7, 46, 47]. However, BMS posed a challenge due to neointimal growth with ISR. Among various therapies, including rotational atherectomy and laser angioplasty, IVBT emerged as more effective option for treating BMS-ISR [37]. Several trials in pre-DES era have consistently shown IVBT to be superior in the treatment of BMS-ISR [48-50]. However, a well-described complication of IVBT is the late catch-up phenomenon, which can lead to the late lumen loss and stent thrombosis [34, 49-52]. The advent of DES aimed at preventing ISR from occurring in the first place, and it was proven to be superior to BMS [53].

After the introduction of DES, it quickly gained popularity and largely dominated the management of ISR, a trend supported by several studies [54, 55]. Furthermore, the outcomes of two landmark trials, SIRS and TAXUS V, which compared DES and IVBT in the treatment of BMS-ISR, solidified the position of DES as the primary choice for BMS-ISR treatment [51, 52].

Utility of IVBT in complex population

While DES is considered superior to IVBT in de novo lesions, recent data suggest the utility of IVBT in DES-ISR [56]. The management of layered DES and overlapping areas of stents is associated with inferior long-term clinical outcomes compared with a single-layered DES [57]. The use of brachytherapy in the treatment of DES-ISR has gathered attention for its drug-free and additional stent layer-free approach, providing an antiproliferative neointimal growth effect through ionizing radiation [21]. A retrospective study by Negi et al. highlighted the safety and efficacy of IVBT in DES-ISR in complex patients, with more than 95% of participants having > 2 prior episodes of target lesion revascularization (TLR) [34].

In a cohort of 186 patients, predominantly with multiple prior TLR episodes and severe lesions, IVBT using 90Sr demonstrated higher procedural success rate and low short-term complication rates. Notably, TLR rates were minimal at 1 months (0.5%), but increased to 3.3% at 6 months, peaked at 19.1% at 2 years, and 20.7% at 3 years. Another study conducted by Mangione et al. reported TLR rate of 24% at 1 year in the treatment of DES-ISR with IVBT, indicating its superiority [58], and our results compare with these favorably.

The applicability of IVBT extends beyond DES-ISR, as evidenced by an observational research conducted by Maluenda et al. [59]. This study involved 563 patients with angina and angiographic evidence of ISR, following DES implantation. Treatment groups included repeat DES (n = 327), IVBT (n = 132), or balloon angioplasty (n = 104). Despite greater lesion complexity and a notably shorter time to previous DES failure in the IVBT group compared with the rest of the cohort, the study showed similarity in the primary endpoint. At the 1-year follow-up, the rates of clinically driven TLR were approximately 10.3%, 14.1%, and 14.6% in the re-DES, IVBT, and balloon angioplasty groups, respectively (p = 0.41). Once again, our study results compare favorably with these outcomes.

Both Negi et al. [34] and Maluenda et al. [59] studies suggest that IVBT is a safe strategy for treating DES-ISR, offering potential advantages, especially in more complex patients with recurrent lesions. Furthermore, several follow-up studies have consistently supported the utility of IVBT in complex patient populations [21, 33, 58, 60-62]. The MACE incidence of our cohorts confirms that of these two studies.

Other approaches in the management of DES-ISR

Addressing SISR remains a significant challenge in interventional cardiology, particularly in the context of DES-ISR, where the optimal therapeutic approach is still uncertain. The exact mechanism of action for DES-ISR remains a subject of controversy, likely stemming from the interplay of various factors, including biological, mechanical, and technical components responsible for ISR. While clear guidelines for treating the initial occurrence of DES-ISR exist in the United States, consensus regarding the treatment of multi-layered SISR has not been established.

DCB: A replacement for IVBT in SISR?

A prospective study conducted in Japan by Habara et al. concluded that DCBs are associated with reduced angiographic late lumen loss (0.18 ±0.45 mm vs. 0.72 ±0.55 mm; p = 0.001), resulting in a notable decline in TLR (8.7% vs. 62.5%; p = 0.0001) [63]. These findings are also supported by the PEPCAD-DES trial involving 110 patients, demonstrating the superiority of DCB angioplasty over plain balloon angioplasty in patients with any type of DES-ISR. The trial indicated late lumen loss (0.43 ±0.61 mm vs. 1.03 ±0.77 mm; p < 0.001) and reduced TLR rates (15.3% vs. 36.8%; p = 0.005) without catch-up at the 3-year follow-up [64, 65]. The ISAR-DESIRE 3 trial enrolled 402 patients and compared paclitaxel-coated balloons (n = 137), paclitaxel-eluting stents (n = 131), and plain balloon angioplasty (n = 134) in patients with DES-ISR. The study concluded that the drug-DCB was non-inferior to DES (p < 0.05) regarding percentage diameter stenosis. Both DCB and DES were superior to the plain balloon angioplasty (plain balloon: 54.1% ±25.0% vs. DCB: 37.4% ±21.8% vs. DES: 38.0% ±21.5%; p < 0.0001 for DCB, DES vs. plain balloon) [66]. A 3-year comparative follow-up of the same study showed no significant differences in TLR, and that paclitaxel-eluting balloons remained superior to plain balloon angioplasty [67]. A recent 10-year follow-up analysis of the ISAR-DESIRE 3 trial by Giacoppo et al., showed the occurrence of the composite endpoint, including all-cause mortality, MI, target lesion thrombosis, or TLR lower in both the DCB and DES compared with the plain balloon group (DCB: 55.9% vs. DES: 62.4% vs. plain balloon; p < 0.001). TLR was significantly lower in both the DCB and DES cohorts when compared with the plain balloon group, revealing no significant difference between the DCB and DES groups [68].

The management of SISR differs significantly between Europe, where DCBs are the standard of care for such patients, and the United States, where the FDA has not yet approved DCBs for DES-ISR. There have been randomized control trials (ISAR-DESIRE 3, PEPCAD, RIBS IV, RESTORE, and BIOLUX), which compared the outcomes of DCB vs. DES in patients with DES-ISR, several of which were powered for clinical endpoints [66, 69-72]. Two other meta-analysis by Giacoppo et al. and Zhu et al. demonstrated that DES implantation was superior to DCB angioplasty in terms of TLR in patients with DES-ISR [68, 73]. Additionally, findings from these studies sparked controversy, given substantial variability observed in several dimensions of these trials, including generation of DES used in the repeat stenting group, participant characteristics, and type of restenosis stent [73]. The controversy surrounding this matter proves challenging to resolve definitively and will require further investigations, especially with an extended follow-up duration, to conclusively assess the efficacy and safety of DES in comparison with DCB for DES-ISR. In this uncertainty, IVBT remains an attractive efficacious primary modality.

Limitations of IVBT

Despite its promising treatment response in patients with SISR, one of the main limitations is the late thrombosis, which is defined as thrombosis post-30 days of IVBT delivery [13, 74]. This can be addressed with dual antiplatelet therapy (DAPT), even though DAPT increases bleeding in high-risk individuals [75]. Other barriers include the additional professional personnel required for IVBT (radiation physicist and radiation oncologist), extensive training, costs of delivery device, catheters, and a secured radiation storage facility. Because of these factors, limited specialty facilities offer IVBT. Additionally, in our study there was no control group, as the patients identified had few options, and we considered that withholding active treatment by placebo or a silent control would be unethical.

Conclusions

Intravascular brachytherapy is a safe and effective treatment option for high-risk complex patients, with minimal procedural and post-procedural complications. It offers a treatment alternative for these patients unsuitable for conventional treatment options while providing the added benefit of symptomatic relief, enhancing their quality of life without administering additional pharmacological agents.

Funding

This research received no external funding.

Disclosures

The study was approved by the Institutional Review Board of Allegheny Health Network.

Notes

[4] Conflicts of interest The authors report no conflict of interest.

References

1 

Hozumi T, Yoshikawa J (eds.). Coronary artery disease in 3-D echocardiography. CRC Press, USA 2007; 1-16.

2 

Tsao CW, Aday AW, Almarzooq ZI et al. Heart disease and stroke statistics-2022 update: A report from the American Heart Association. Circulation 2022; 145: E153-E639.

3 

MacNeill BD, Jang IK, Wong P. Coronary stents in clinical, interventional and investigational thrombocardiology. Becker R, Harrington R (Eds.). CRC Press (3rd Ed), USA 2022; 453-472.

4 

Brown JC, Gerhardt TE, Kwon E. Risk factors for coronary artery disease. In: StatPearls Publishing, StatPearls, USA. https://pubmed.ncbi.nlm.nih.gov/32119297/

5 

Dhruva SS, Parzynski CS, Gamble GM et al. Attribution of adverse events following coronary stent placement identified using administrative claims data. J Am Heart Assoc 2020; 9: e013606.

6 

Taniwaki M, Stefanini GG, Silber S et al. 4-year clinical outcomes and predictors of repeat revascularization in patients treated with new-generation drug-eluting stents: a report from the RESOLUTE All-Comers trial (A Randomized Comparison of a Zotarolimus-Eluting Stent With an Everolimus-Eluting Stent for Percutaneous Coronary Intervention). J Am Coll Cardiol 2014; 63: 1617-1625.

7 

Fischman DL, Leon MB, Baim DS et al. A randomized comparison of coronary-stent placement and balloon angioplasty in the treatment of coronary artery disease. N Engl J Med 1994; 331: 496-501.

8 

Serruys PW, de Jaegere P, Kiemeneij F et al. A comparison of balloon-expandable-stent implantation with balloon angioplasty in patients with coronary artery disease. N Engl J Med 1994; 331: 489-495.

9 

Serruys PW, Van Hout B, Bonnier H et al. Randomised comparison of implantation of heparin-coated stents with balloon angioplasty in selected patients with coronary artery disease (Benestent II). Lancet 1998; 352: 673-681.

10 

Post MJ, Borst C, Kuntz RE. The relative importance of arterial remodeling compared with intimal hyperplasia in lumen renarrowing after balloon angioplasty. A study in the normal rabbit and the hypercholesterolemic Yucatan micropig. Circulation 1994; 89: 2816-2821.

11 

Mintz GS, Popma JJ, Hong MK et al. Intravascular ultrasound to discern device-specific effects and mechanisms of restenosis. Am J Cardiol 1996; 78: 18-22.

12 

Rebel RE, Aude MH, Öpp HW et al. Coronary-artery stenting compared with balloon angioplasty for restenosis after initial balloon angioplasty. N Engl J Med 1998; 339: 1672-1678.

13 

Leon MB, Teirstein PS, Moses JW et al. Localized intracoronary gamma-radiation therapy to inhibit the recurrence of restenosis after stenting. N Engl J Med 2001; 344: 250-256.

14 

Dangas GD, Claessen BE, Caixeta A et al. In-stent restenosis in the drug-eluting stent era. J Am Coll Cardiol 2010; 56: 1897-1907.

15 

Mehran R, Dangas G, Abizaid AS et al. Angiographic patterns of in-stent restenosis: Classification and implications for long-term outcome. Circulation 1999; 100: 1872-1878.

16 

Kuntz RE, Baim DS. Defining coronary restenosis. Newer clinical and angiographic paradigms. Circulation 1993; 88: 1310-1323.

17 

Kim SW, Mintz GS, Escolar E et al. An intravascular ultrasound analysis of the mechanisms of restenosis comparing drug-eluting stents with brachytherapy. Am J Cardiol 2006; 97: 1292-1298.

18 

Dibra A, Kastrati A, Alfonso F et al. Effectiveness of drug-eluting stents in patients with bare-metal in-stent restenosis: meta-analysis of randomized trials. J Am Coll Cardiol 2007; 49: 616-623.

19 

Sethi A, Malhotra G, Singh S et al. Efficacy of various percutaneous interventions for in-stent restenosis: comprehensive network meta-analysis of randomized controlled trials. Circ Cardiovasc Interv 2015; 8: e002778.

20 

Buccheri D, Piraino D, Andolina G et al. Understanding and managing in-stent restenosis: a review of clinical data, from pathogenesis to treatment. J Thorac Dis 2016; 8: E1150.

21 

Megaly M, Glogoza M, Xenogiannis I et al. Outcomes of intravascular brachytherapy for recurrent drug-eluting in-stent restenosis. Catheter Cardiovasc Interv 2021; 97: 32-38.

22 

Shlofmitz E, Iantorno M, Waksman R. Restenosis of drug-eluting stents: A new classification system based on disease mechanism to guide treatment and state-of-the-art review. Circ Cardiovasc Interv 2019; 12: e007023.

23 

Kubo S, Kadota K, Otsuru S et al. Optimal treatment of recurrent restenosis lesions after drug-eluting stent implantation for in-stent restenosis lesions. EuroIntervention 2013; 9: 788-796.

24 

Yabushita H, Kawamoto H, Fujino Y et al. Clinical outcomes of drug-eluting balloon for in-stent restenosis based on the number of metallic layers. Circ Cardiovasc Interv 2018; 11: e005935.

25 

Theodoropoulos K, Mennuni MG, Dangas GD et al. Resistant in-stent restenosis in the drug eluting stent era. Catheter Cardiovasc Interv 2016; 88: 777-785.

26 

Siontis GCM, Stefanini GG, Mavridis D et al. Percutaneous coronary interventional strategies for treatment of in-stent restenosis: a network meta-analysis. Lancet 2015; 386: 655-664.

27 

Neumann FJ, Sousa-Uva M, Ahlsson A et al. 2018 ESC/EACTS Guidelines on myocardial revascularization. Eur Heart J 2019; 40: 87-165.

28 

Levine GN, Bates ER, Blankenship JC et al. 2011 ACCF/AHA/SCAI guideline for percutaneous coronary intervention. Circulation 2011; 124: 574-651.

29 

Waksman R, Iantorno M. Refractory in-stent restenosis: Improving outcomes by standardizing our approach. Curr Cardiol Rep 2018; 20: 777-785.

30 

Waksman R, White RL, Chan RC et al. Intracoronary gamma-radiation therapy after angioplasty inhibits recurrence in patients with in-stent restenosis. Circulation 2000; 101: 2165-2171.

31 

Hansrani M, Overbeck K, Smout J et al. Intravascular brachytherapy: a systematic review of its role in reducing restenosis after endovascular treatment in peripheral arterial disease. Eur J Vasc Endovasc Surg 2002; 24: 377-382.

32 

Cutlip DE, Chauhan MS, Baim DS et al. Clinical restenosis after coronary stenting: Perspectives from multicenter clinical trials. J Am Coll Cardiol 2002; 40: 2082-2089.

33 

Varghese MJ, Bhatheja S, Baber U et al. Intravascular brachytherapy for the management of repeated multimetal-layered drug-eluting coronary stent restenosis. Circ Cardiovasc Interv 2018; 11: e006832.

34 

Negi SI, Torguson R, Gai J et al. Intracoronary brachytherapy for recurrent drug-eluting stent failure. JACC Cardiovasc Interv 2016; 9: 1259-1265.

35 

Nath R, Roberts KB. Vascular irradiation for the prevention of restenosis after angioplasty: A new application for radiotherapy. Int J Radiat Oncol Biol Phys 1996; 36: 977-979.

36 

Lobato EB. Care of the patient with coronary stents undergoing noncardiac surgery in essentials of cardiac anesthesia for noncardiac surgery. Kaplan JA (Ed.), Cronin B, Maus T (Assoc. Eds.). Essentials of cardiac anesthesia for noncardiac surgery. Elsevier, Philadelphia, PA 2019.

37 

Kim MS, Dean LS. In-stent restenosis. Cardiovasc Ther 2011; 29: 190-198.

38 

Alfonso F, Byrne RA, Rivero F et al. Current treatment of in-stent restenosis. J Am Coll Cardiol 2014; 63: 2659-2673.

39 

Bønaa KH, Mannsverk J, Wiseth R et al. Drug-eluting or bare-metal stents for coronary artery disease. N Engl J Med 2016; 375: 1242-1252.

40 

Zhang BC, Karanasos A, Regar E. OCT demonstrating neoatherosclerosis as part of the continuous process of coronary artery disease. Herz 2015; 40: 845-854.

41 

Looser PM, Kim LK, Feldman DN. In-stent restenosis: pathophysiology and treatment. Curr Treat Options Cardiovasc Med 2016; 18: 10.

42 

Shlofmitz E, Iantorno M, Waksman R. Restenosis of drug-eluting stents: a new classification system based on disease mechanism to guide treatment and state-of-the-art review. Circ Cardiovasc Interv 2019; 12: e007023.

43 

Nakamura D, Yasumura K, Nakamura H et al. Different neoatherosclerosis patterns in drug-eluting-and bare-metal stent restenosis–optical coherence tomography study. Circ J 2019; 83: 313-319.

44 

Waksman R, Rodriguez JC, Robinson KA et al. Effect of intravascular irradiation on cell proliferation, apoptosis, and vascular remodeling after balloon overstretch injury of porcine coronary arteries. Circulation 1997; 96: 1944-1952.

45 

Hall EJ. Radiobiology for the radiologist. 8th ed. Wolters Kluwer, The Netherlands.

46 

Serruys PW, de Jaegere P, Kiemeneij F et al. A comparison of balloon-expandable-stent implantation with balloon angioplasty in patients with coronary artery disease. Benestent Study Group. N Engl J Med 1994; 331: 489-495.

47 

Sigwart U, Puel J, Mirkovitch V et al. Intravascular stents to prevent occlusion and restenosis after transluminal angioplasty. N Engl J Med 1987; 316: 701-706.

48 

Teirstein PS, Massullo V, Jani S et al. Catheter-based radiotherapy to inhibit restenosis after coronary stenting. N Engl J Med 1997; 336: 1697-1703.

49 

Waksman R, White RL, Chan RC et al. Intracoronary γ-radiation therapy after angioplasty inhibits recurrence in patients with in-stent restenosis. Circulation 2000; 101: 2165-2171.

50 

Waksman R, Cheneau E, Ajani AE et al. Intracoronary radiation therapy improves the clinical and angiographic outcomes of diffuse in-stent restenotic lesions: results of the Washington Radiation for In-Stent Restenosis Trial for Long Lesions (Long WRIST) Studies. Circulation 2003; 107: 1744-1749.

51 

Holmes DR, Teirstein P, Satler L et al. Sirolimus-eluting stents vs vascular brachytherapy for in-stent restenosis within bare-metal stents: the SISR randomized trial. JAMA 2006; 295: 1264-1273.

52 

Stone GW, Ellis SG, O’Shaughnessy CD et al. Paclitaxel-eluting stents vs vascular brachytherapy for in-stent restenosis within bare-metal stents: the TAXUS V ISR randomized trial. JAMA 2006; 295: 1253-1263.

53 

Morice MC, Serruys PW, Sousa JE et al. A randomized comparison of a sirolimus-eluting stent with a standard stent for coronary revascularization. N Engl J Med 2002; 346: 1773-1780.

54 

Piccolo R, Stefanini GG, Franzone A et al. Safety and efficacy of resolute zotarolimus-eluting stents compared with everolimus-eluting stents. Circ Cardiovasc Interv 2015; 8: e002223.

55 

Kastrati A, Mehilli J, Von Beckerath N et al. Sirolimus-eluting stent or paclitaxel-eluting stent vs balloon angioplasty for prevention of recurrences in patients with coronary in-stent restenosis: a randomized controlled trial. JAMA 2005; 293: 165-171.

56 

Detloff LR, Ho EC, Ellis SG et al. Coronary intravascular brachytherapy for in-stent restenosis: A review of the contemporary literature. Brachytherapy 2022; 21: 692-702.

57 

Räber L, Jüni P, Löffel L et al. Impact of stent overlap on angiographic and long-term clinical outcome in patients undergoing drug-eluting stent implantation. J Am Coll Cardiol 2010; 55: 1178-1188.

58 

Mangione FM, Jatene T, Badr Eslam R et al. Usefulness of intracoronary brachytherapy for patients with resistant drug-eluting stent restenosis. Am J Cardiol 2017; 120: 369-373.

59 

Maluenda G, Ben-Dor I, Gaglia MA et al. Clinical outcomes and treatment after drug-eluting stent failure: the absence of traditional risk factors for in-stent restenosis. Circ Cardiovasc Interv 2012; 5: 12-19.

60 

Megaly M, Glogoza M, Xenogiannis I et al. Coronary intravascular brachytherapy for recurrent coronary drug-eluting stent in-stent restenosis: a systematic review and meta-analysis. Cardiovasc Revasc Med 2021; 23: 28-35.

61 

Bonello L, Kaneshige K, De Labriolle A et al. Vascular brachytherapy for patients with drug-eluting stent restenosis. J Interv Cardiol 2008; 21: 528-534.

62 

Meraj PM, Patel K, Patel A et al. Northwell intracoronary brachytherapy for the treatment of recurrent drug eluting stent in-stent restenosis (NITDI study group). Catheter Cardiovasc Interv 2021; 97: 41-46.

63 

Habara S, Mitsudo K, Kadota K et al. Effectiveness of paclitaxel-eluting balloon catheter in patients with sirolimus-eluting stent restenosis. JACC Cardiovasc Interv 2011; 4: 149-154.

64 

Rittger H, Waliszewski M, Brachmann J et al. Long-term outcomes after treatment with a paclitaxel-coated balloon versus balloon angioplasty: Insights from the PEPCAD-DES study (Treatment of Drug-eluting Stent [DES] In-Stent Restenosis With SeQuent Please Paclitaxel-Coated Percutaneous Transluminal Coronary Angioplasty [PTCA] Catheter). JACC Cardiovasc Interv 2015; 8: 1695-1700.

65 

Rittger H, Brachmann J, Sinha AM et al. A randomized, multicenter, single-blinded trial comparing paclitaxel-coated balloon angioplasty with plain balloon angioplasty in drug-eluting stent restenosis: The PEPCAD-DES study. J Am Coll Cardiol 2012; 59: 1377-1382.

66 

Byrne RA, Neumann FJ, Mehilli J et al. Paclitaxel-eluting balloons, paclitaxel-eluting stents, and balloon angioplasty in patients with restenosis after implantation of a drug-eluting stent (ISAR-DESIRE 3): A randomised, open-label trial. Lancet 2013; 381: 461-467.

67 

Kufner S, Cassese S, Valeskini M et al. Long-term efficacy and safety of paclitaxel-eluting balloon for the treatment of drug-eluting stent restenosis: 3-year results of a randomized controlled trial. JACC Cardiovasc Interv 2015; 8: 877-884.

68 

Giacoppo D, Alvarez-Covarrubias HA, Koch T et al. Coronary artery restenosis treatment with plain balloon, drug-coated balloon, or drug-eluting stent: 10-year outcomes of the ISAR-DESIRE 3 trial. Eur Heart J 2023; 44: 1343-1357.

69 

Jensen CJ, Richardt G, Tölg R et al. Angiographic and clinical performance of a paclitaxel-coated balloon compared to a second-generation sirolimus-eluting stent in patients with in-stent restenosis: the BIOLUX randomised controlled trial. EuroIntervention 2018; 14: 1096-1103.

70 

Wong YTA, Kang DY, Lee JB et al. Comparison of drug-eluting stents and drug-coated balloon for the treatment of drug-eluting coronary stent restenosis: A randomized RESTORE trial. Am Heart J 2018; 197: 35-42.

71 

Alfonso F, Pérez-Vizcayno MJ, Cárdenas A et al. A prospective randomized trial of drug-eluting balloons versus everolimus-eluting stents in patients with in-stent restenosis of drug-eluting stents: The RIBS IV Randomized Clinical Trial. J Am Coll Cardiol 2015; 66: 23-33.

72 

Xu B, Gao R, Wang J et al. A prospective, multicenter, randomized trial of paclitaxel-coated balloon versus paclitaxel-eluting stent for the treatment of drug-eluting stent in-stent restenosis: results from the PEPCAD China ISR trial. JACC Cardiovasc Interv 2014; 7: 204-211.

73 

Zhu Y, Liu K, Kong X et al. Comparison of drug-coated balloon angioplasty vs. drug-eluting stent implantation for drug-eluting stent restenosis in the routine clinical practice: A meta-analysis of randomized controlled trials. Front Cardiovasc Med 2021; 8: 766088.

74 

Serruys PW, Wijns W, Sianos G et al. Direct stenting versus direct stenting followed by centered beta-radiation with intravascular ultrasound-guided dosimetry and long-term anti-platelet treatment. Results of a randomized trial: Beta-Radiation Investigation with Direct stenting and Galileo in Europe (BRIDGE). J Am Coll Cardiol 2004; 44: 528-537.

75 

Sharma R, Kumar P, Prashanth SP et al. Dual antiplatelet therapy in coronary artery disease. Cardiol Ther 2020; 9: 349-361.

Copyright: © 2025 Termedia Sp. z o. o. This is an Open Access article distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International (CC BY-NC-SA 4.0) License (http://creativecommons.org/licenses/by-nc-sa/4.0/), allowing third parties to copy and redistribute the material in any medium or format and to remix, transform, and build upon the material, provided the original work is properly cited and states its license.
  
Termedia
About us Contact
Copyright notice Privacy policy Advertising policy Contact us
Quick links
Journals Books eBooks Events
© 2026 Termedia Sp. z o.o.
Developed by Termedia.