There are two processing methods that are being used for intravascular OCT imaging: Time Domain OCT (TD-OCT), and the recently introduced Fourier Domain OCT (FD-OCT), which is also known as second generation OCT, Frequency Domain OCT, or Optical Frequency Domain Imaging (OFDI). FD-OCT systems can record A-lines at a very high speed, while improving noise-signal ratios resulting in greater penetration depth, without loss of vital detail or resolution. In this way, imaging acquisition time and contrast used is reduced, while longer pullbacks are acquired [8].

Currently available FD-OCT systems are utilizing a short rapid-exchange monorail catheter for mounting of the optical probe. The optical signal is transmitted by a single-mode fiber, automatically mounted on the catheter, the focus of which is approximately 1 mm outside the catheter. In order to scan the vessel lengthwise, the catheter imaging tip is pulled back while rotating, inside a transparent sheath, allowing for retrieval of consecutive cross-sectional images for a length of 50–70 mm from the coronary artery. Both rotary and pullback motion are driven proximally by a motor outside the patient. For image acquisition, the FD-OCT catheter is initially advanced with the aid of a conventional guidewire distally to the desired segment, while the catheter position is indicated by radio-opaque markers. In order to create a blood-free environment during the acquisition, contrast warmed to 37 °C is injected, either manually, or by a power injector at a rate of 3–4 mL/sec. Pullback of the optical fiber is being performed simultaneously with the contrast injection.

The first experimental and human studies of TD-OCT have shown the safety and feasibility of OCT imaging using a proximal occlusion balloon for blood clearance [9]. An alternative technique eliminating the need for proximal occlusion has also demonstrated a favorable safety profile [10]. In the first systematic attempt from a multicenter registry of 468 patients undergoing TD-OCT imaging either with the occlusive or the non-occlusive technique, to record the safety of optical coherence tomography, use of the non-occlusive technique was associated with a reduction in the rate of transient complications during image acquisition such as chest pain and ECG changes [11••]. The introduction of FD-OCT led to a significant improvement in the rate of images of usable quality by simultaneously reducing acquisition time and the rate of transient chest pain and ECG changes [8]. Furthermore, use of a FD-OCT system for guidance of intervention was associated with a favorable safety profile [12].

OCT is an imaging method that can accurately measure lumen and stent dimensions with high agreement with histological specimens and characterize tissue with high sensitivity and specificity. By OCT, it is possible to visualize all three arterial layers in a normal coronary artery, in accordance with pathological specimens [13]. OCT allows differentiation of fibrous, fibrocalcific, and lipid-rich tissue by visual assessment of the standard intensity image [14]. Briefly, fibrous plaque is seen as a high-intensity, low-attenuation area, lipid as a low-intensity, high-attenuation area with diffuse borders, while calcium as low-intensity, low-attenuation area with sharp borders (Fig. 1) [14]. OCT can also detect thrombus with very high sensitivity and specificity, and allows for distinction between red (erythrocyte-rich) and white (platelet-rich) thrombus [15].

Several studies have validated the ability of OCT to perform quantitative measurements of the lumen and stent area [7••, 16, 17]. Meanwhile, in vivo studies have confirmed that there is high correlation between OCT and IVUS measurements of vessel and stent dimensions, as well as that there is very low intra-observer and inter-observer variability in the assessment of stent and vessel area [18]. Measurements acquired by FD-OCT systems seem to be equally accurate and reproducible [19]. The recent introduction of algorithms allowing for the automated quantitative assessment of lumen dimensions enables the acceleration of the analysis process [20‐22]. Various algorithms and software packages have been suggested for this approach [20], while the ability of these automatic quantification programs to detect with high correlation with histology and manual interpretation the luminal and stent borders allows for the rapid online assessment of the degree of stenosis, reference site diameter, and degree of neointimal hyperplasia [21, 22].

Accurate measurements of lumen area by OCT can be used for the evaluation of intermediate lesions. It has been shown in IVUS studies, that angiography often underestimates the plaque burden and the severity of stenosis [23]. Thus, evaluation of intermediate lesions has been a focus of invasive imaging. Functional assessment of intermediate lesions using fractional flow reserve (FFR) in patients with stable disease has been shown in large-scale studies to be linked with improved outcomes as it overcomes limitations of angiography [24]. Despite the existence of IVUS studies assessing quantitative indices of stenosis as a marker of the functional significance of a lesion, it remains questionable whether functional measurements can be replaced by anatomic measurements by IVUS or OCT. Taking into account, however, that various parameters, such as lesion length, lesion location, and plaque burden are factors also affecting the functional significance of a lesion, it is doubtful that the physiological significance of a lesion can be accurately assessed by measurement of minimal lumen area alone [25]. Moreover, a recent evaluation of IVUS and OCT to assess the physiological significance of a stenosis revealed that despite OCT measurements of minimal lumen area having greater diagnostic potential than IVUS for the assessment of the physiological significance of intermediate stenosis, anatomic lesion assessment by either modality correlates poorly to physiologic measurements performed by FFR [26]. Consequently, the current golden standard to assess hemodynamic relevance in a patient with stable angina is functional measurement by FFR (what to treat?), while OCT is helpful in guiding the procedure (how to treat?) or identification of the culprit and thrombosed lesion in acute coronary syndromes with intermediate lesions.

A field were OCT could substantially improve preprocedural assessment is in the evaluation of hazy lesions (Fig. 2). It is known that angiographic haziness could be due to a variety of morphological features such as thrombus, heavy calcification, extreme tortuosity, and intimal dissection. There have been several reports of utilizing OCT for the assessment of the nature of haziness, that have ranged from extreme vessel tortuosity to vessel dissection and recanalised thrombus [27‐29]. Furthermore, the use of IVUS would be less helpful in such cases, as its diagnostic accuracy for complicated plaque and thrombus detection is limited [30].

Optical coherence tomography can also aid decision making in cases of acute coronary syndromes in patients where coronary spasm appears to be the culprit. Use of OCT in this subset of patients can exclude the presence of culprit atheromatic plaques and/or thrombus. The association of plaque morphology with coronary spasm has been evaluated by OCT, showing that the main underlying morphology is transient intima-media thickening [31]. Multiple lumen irregularities observed during the episode consisting of intimal bumps and intimal gathering disappear after intracoronary nitrate administration, giving place to normal vessel morphology [31].

One of the advantages of OCT is that it can assist in the preprocedural evaluation of coronary lesions by providing information about the morphology of the lesions. A small study recently evaluated the complementary use of FD-OCT with FFR in order to assess angiographically ambiguous lesions. In this study, FFR was used in order to provide information about the functional significance of these lesions, while FD-OCT was used in order to assess the presence of unstable plaques and guide decision making in cases of ACS and FFR values >0.80 [32]. Moreover, the underlying plaque type has been associated with the outcome of the intervention. The presence of lipid-rich plaques by OCT has been associated with greater incidence of non-reflow and greater rise in biomarkers of cardiac necrosis in several studies [33]. Additionally, patients with unstable angina compared to stable patients had greater rates of acute malapposition and tissue protrusion post PCI, while they had higher rates of malapposition and incomplete coverage at 9-month follow-up, implying an association between complicated plaque morphology—which was more common in the unstable angina group—with impaired vessel healing after stenting [34].

It remains to be proven whether qualitative assessment of non-culprit lesions can guide decision for treatment and improve patient-related outcomes. A recent intravascular ultrasound study suggested an association of the presence of a non-culprit lesion with small lumen area, large plaque burden and plaque morphology, as identified by radiofrequency ultrasound analysis, with subsequent re-hospitalizations and events [6]. However, the prognostic value of intravascular ultrasound with radiofrequency signal analysis for vulnerable plaque identification and risk stratification still needs to be established.

OCT can be used in order to guide decisions about treatment before the procedure. As discussed above, OCT can provide precise area measurements not only of the minimal lumen, but of proximal and distal reference sites as well, and define the lesion length. Therefore, preprocedural measurements by OCT can aid in the proper selection of balloon and stent dimensions. Selection of appropriate balloon size using OCT measurements has been performed in a series of patients undergoing cutting balloon angioplasty for the treatment of in-stent restenosis [35]. Furthermore, OCT has also been used for selection of treatment strategy on the basis of lesion morphology. Given that OCT can quantify calcifications of the target site more accurately than IVUS [36], it could better assess the need for targeted therapies (Fig. 3). In a recent study, pre-interventional OCT assessment of plaque morphology guided the selection of dedicated treatments such as rotablation, thrombectomy, and cutting balloon in one third of patients [37•]. In the same study, decision to defer angioplasty was taken in 18 % of the patients using criteria of IVUS guidance [38], for assessing the severity of the lesion.

One of the advantages of OCT guidance is that it can help precisely identify the optimal segment for stent deployment, the so-called “landing zone” (Fig. 4). It has been shown that multiple plaque morphologies may be present in the culprit lesion of a patient with ACS [39]. Moreover, the longitudinal analysis of culprit lesions of ACS has demonstrated that in the majority of cases there is geographic mismatch of the minimal lumen site with the rupture site [40•], indicating the presence of necrotic core plaques in sites remote to the site of the greatest stenosis. Although there is not definitive evidence that stenting should also cover lipid-rich plaques located in shoulder areas, it has been shown that presence of such areas in the edge of the stent is associated with edge dissection, as is the presence of fibrocalcific plaques [41]. Additionally, pathologic studies have shown the association of late stent thrombosis with the presence of struts penetrating areas of necrotic core [42], while as mentioned earlier, possible stent-induced disruption of such areas could lead to impaired vascular healing or raise in cardiac necrosis biomarkers [33, 34].

While invasive imaging generally offers high spatial resolution, it can be challenging to consolidate the information gained by invasive imaging technologies with the angiogram, and especially, to ensure correct spatial orientation. This is true for all angiographically silent lesions, whereas this phenomenon might be a consequence of vessel overlap, foreshortening or the inability to visualize a complex three-dimensional structure correctly in a two-dimensional image. Often operators use side branches as observed in both imaging modalities as landmarks. This approach is not always the optimal, as side branch ostia are not always clearly visible by angiography and also the assumed calibre of a particular side branch can be underestimated. Currently, a number of technical solutions to this problem are being developed, including the use of pulsed fluoroscopy to track the imaging catheter in real time (Siemens Medical prototype, Erlangen, Germany) [43] or alternatively, approaches for software enabled synchronization of three-dimensional angiography with invasive imaging pullbacks are being developed (Medis Medical Imaging Systems BV, Leiden, The Netherlands) (Fig. 4) [44]. The ultimate goal is an online co-registration of the invasive imaging modality with the coronary angiogram, allowing the operator to scroll through a synchronized dataset. Such information could be useful for planning of the most appropriate interventional strategy and for the longitudinal assessment of atherosclerotic lesions.

OCT can also be a tool for guidance during complex procedures. There have been reports of OCT guidance in chronic total occlusions (CTOs) [45]. In such cases, OCT can be used to identify the entry point of the occlusion and to confirm that the guidewire is indeed in the true vessel lumen and has not entered a false lumen. The development of forward-looking OCT catheters will enable the guidance of a CTO crossing by continuous visualization of the position of the guidewire relative to the microchannels.

Bifurcation lesion stenting is another potential application of OCT guidance. By 3-dimensional reconstruction of OCT images it is possible to produce images that indicate the relative position of the main vessel and the side-branch and help select a suitable strategy [46]. Furthermore, three-dimensional models of coronary arteries can help identify the point of re-crossing of a guidewire in a side branch through the cells of a stent implanted in the main vessel, and evaluate possible presence of struts at the ostia of the side branches following kissing balloon dilation [47]. The development of online reconstructions that incorporate three-dimensional angiography and optical coherence tomography images could improve real-time guidance in these subsets of lesions [44, 48•].