1.

Introduction

Prostate cancer diagnosis is based on prostate specific antigen (PSA) dosage and digital rectal examination. If the test is positive, a biopsy is conducted and guided by ultrasound imaging. However, current ultrasound imaging techniques are unable to detect tumors of small and medium size, and biopsies are performed in the prostate by following a systematic sampling pattern. This pattern covers the areas having the highest rates of cancer occurrence but some tumors may nonetheless remain undetected. Consequently, the only way to improve detection is to increase the number of biopsies. But this number cannot be increased because it may lead to major complications (6.6% of patients) such as acute prostatitis (3.8%), acute urinary retention (2.1%), hematuria (1.9%), rectal bleeding (0.2%), epididymitis (0.2%), sepsis (0.05%), and vasovagal syncope (0.05%).¹ Finding a way to guide biopsies to tumors may decrease the rate of false negative cases and improve patient well-being.

Bimodal optical and ultrasound methods have already been proposed to solve this problem. The combined use of these complementary methods seems promising: ultrasound provides morphological information and optical detection may guide the biopsy needle to the tumor. As ultrasound probes are used in routine examinations, the addition of optics would not involve a drastic change in the clinical protocol, but would facilitate the penetration of this technology. Moreover, optical detection can be easily integrated in an ultrasound probe through the use of optical fibers. Last, the morphological information provided by ultrasound could be used to improve optical location of tumors, as shown in a simulation performed by Xu ²

To discriminate between cancerous and healthy tissues, some authors used the fact that tumors are more vascularized than the surrounding tissues to measure attenuation of the near-infrared (NIR) light.³ Optical characteristics (absorption and diffusion) of healthy and cancerous prostates were clinically measured.⁴ In order to design an optimized optical probe, simulations were conducted to evaluate the best distribution of optical fibers.⁵ A bimodal endorectal probe combining ultrasound and optical measurements, based on NIR absorption by intrinsic or endogenous chromophores, was proposed and successfully tested in preclinical trials on canine prostates with venereal tumors.⁶ Nevertheless, all of these methods are based on the intrinsic or endogenous contrast between tumoral and healthy tissues. Actually, to detect cancer cells at an early stage, a stronger contrast between cancerous and healthy cells is required. Agarwal ⁷ proposed enhancing the contrast by means of optoacoustic measurements on specifically functionalized gold nanoparticles which also act as thermotherapy agents.

Using fluorescence for in vivo prostate cancer diagnosis seems to be another promising way to improve the specificity of detection. However, the time involved in developing these methods was lengthened by the absence of specific fluorescent markers. In 2008, Pu ⁸ showed the efficacy of Cytate, a fluorescence marker derivative of Indocyanine Green (ICG), which conjugates to receptors on prostate cancer cells.

Although fluorescence has a huge potential to improve the specificity of detection, it has to contend with weaker signals than in NIR absorption measurements. This drawback implies the need for a high-power laser source and time-resolved detectors to locate the origins of fluorescence emissions more accurately. Fluorescence diffuse optical tomography (FDOT) techniques were successfully applied to the detection of tumors in small animals,⁹ enabling imaging through a greater thickness of breast tissue $(<1.5\mathrm{cm})$ . The small-animal approach of FDOT was even applied to human breast cancer¹⁰ thanks to the weak light absorption coefficient of breasts $({\mu }_a\approx 0.03{\mathrm{cm}}^{-1})$ , which compensates for the greater thickness $\left(5\text{to}9\mathrm{cm}\right)$ .

Applying these techniques to prostate cancer diagnosis is a real challenge given that the absorption coefficient of prostatic tissues is very high ( ${\mu }_a\approx 0.3{\mathrm{cm}}^{-1}$ ; Ref. 4), with a diffusion coefficient equivalent to lungs of small animals $({\mu }_s^{\prime }\approx 7{\mathrm{cm}}^{-1})$ . Moreover, the geometry of an endorectal cavity is very confined, thus limiting us to reflection measurements that generate a high level of background signal noise (autofluorescence).

This article describes the first transrectal probe based on time-resolved FDOT. This probe was used to take measurements on fluorescent inclusions of various concentrations and located at fixed depths inside the prostate phantom. A reconstruction algorithm based on time-of-flight analysis was used to locate these inclusions accurately. Linearity experiments were also performed. Last, the system resolution was evaluated through simulation and the results discussed.

2.

Materials and Methods

2.1.

Description of the Optical and Ultrasound System

The schematic diagram of the optical system is illustrated in Fig. 1 . It consists mainly of a pulsed titanium-sapphire laser, a transrectal optical probe, and a high rate imager (HRI). The laser (Spectra-Physics) was tuned to produce $50\text{-}\mathrm{fs}$ pulses at $770\mathrm{nm}$ and $80\text{-}\mathrm{MHz}$ frequency. The average laser power $\left(10\mathrm{mW}\right)$ provides enough energy to penetrate deeply inside the phantom and to excite the inclusion. Its wavelength was chosen to fit the absorption peak of the fluorescing inclusion. The laser is filtered through a $770\text{-}\mathrm{nm}$ bandpass filter (Thorlabs FB770). The excitation fiber selection is performed by a magnifying lens (Zeiss $10\times$ NA: 0.2) mounted on a displacement plate and moved in front of the desired fiber. The excitation fiber bundle is composed of six standard $62.5\text{-}\mu \mathrm{m}$ -diam silica fibers.

Fig. 1

(a) Diagram of the time-resolved optical system. For simplicity’s sake, only three out of six excitation fibers and two out of four-detection fibers are represented. (b) Photo of the optical transrectal probe gently pressed against the prostate phantom. The fluorescing inclusion is located $1.2\mathrm{cm}$ below the surface of the phantom.

Figure 2 shows the drawings of the optical probe. Its dimensions are $15\times 2{\mathrm{cm}}^2$ . The axial ultrasound imaging transducer is located at the outer end of the probe. Both excitation and emission fibers are housed between the plastic shell of the probe and the transducer electronics. The optical head consists of 10 channels of fibers, 6 for excitation and 4 for fluorescence detection. The minimum source–detector separation distance of $10\mathrm{mm}$ ensures a good compromise between fluorescence intensity collection and background signal reduction. The emission fiber bundle is composed of four plastic high-aperture fibers (inner $\text{diameter}=1\mathrm{mm}$ , $\mathrm{NA}=0.46$ , $\text{length}=0.15\mathrm{m}$ ) to optimize fluorescence collection. The signals from the four detection fibers are collected by a macrolens (Zeiss $6.3\times$ ). To handle the high level of excitation of the signal collected by the detection fiber, both Notch and Razoredge filters were used (NF01-785U-25 and LP02-785RS-25 Semrock)

Fig. 2

Diagram of the transrectal probe. (a) Front view of the bimodal optical head, with source and detector indexes. (b) Side view of the transrectal probe showing optical fiber angles. (c) Perspective view of the probe with handle (1).

The fluorescence is detected by an intensified high-rate imager (Kentech). Inside the HRI, the photons are changed into electrons by a photocathode and amplified by a multichannel plate (MCP). The photons generated by the phosphorous screen are focused and acquired by a $12\text{-bit}$ cooled CCD camera (Hamamatsu Orca-ER). An electronic gating system drives the high voltage of the MCP for time intervals of $300\mathrm{ps}$ . The time-dependent distribution of the fluorescence signal was measured by the use of a programmable delay system (Kentech).

To illustrate the feasibility of bimodal detection, auxiliary values were collected by combining time-resolved fluorescence and ultrasonic measurements. These experiments were not carried out with the transrectal probe but with a commercial system-[Ultrasonic 500RP by Ultrasonix Medical Corporation; Fig. 3d ], which gives a planar view of the prostate phantom and can be displaced above the phantom in a more convenient way than a transrectal probe. The ultrasound system is mounted on a displacement table and acquires one planar image every $1\mathrm{mm}$ , in order to obtain a 3-D image of the prostate phantom. The ultrasound probe is positioned above the phantom, and several $1\text{-}\mathrm{mm}$ -spaced transverse scans are acquired. The acoustic probe has a $6.7\text{-}\mathrm{MHz}$ central frequency. The acoustic beam is focused near the central part of the phantom. Optical measurements were taken with the same laser and detection system but without excitation and detection fiber networks and in planar geometry. This work was previously described in Ref. 11. After this bimodal acquisition, the optical and ultrasonic slices are superimposed by means of standard image processing software.

Fig. 3

(a) Ultrasonic image of a healthy prostate. This image shows the three different kinds of tissues simulated by the phantom: rectum wall, central zone, and surrounding tissues. (b) Diagram of the prostate phantom [rectum wall (R), central zone (P), and surrounding tissues (S)]. (c) Photo of a previous version of the prostate phantom with the fluorescent inclusion (fluorescent glass) inserted $2\mathrm{cm}$ below the surface. (d) Photo of the prostate phantom placed inside the vat and being scanned by the Ultrasonic 500RP system.

3.

Results

Figure 4 shows the reconstructed fluorescent yield of a $1\text{-}\mu \mathrm{M}$ capillary tube obtained with the transrectal probe (six excitation and four detection fibers). Its $x,y,z$ position was correctly recovered.

Fig. 4

(a) Reconstruction results are represented by a series of slices in the $xy$ plane, each image representing a slice at a given height $z$ inside the phantom. (b) 3-D view of the previous reconstruction. Source (red dots) and detection (blue dots) fibers are also plotted. The reconstruction fluorescent inclusion was found at $z=2.2\mathrm{cm}$ . The difference between the real and reconstructed position of the inclusion $(z=2\mathrm{cm})$ can be explained by the phantom surface deformation due to the probe. (Color online only.)

Location sensitivity of the system was determined by simulations. The time-dependent fluorescence signal due to an inclusion located at a depth of $1.2\mathrm{cm}$ was simulated by using an analytical propagation model and an exponential decay for the fluorophore. The background signal was taken to be leakage from the excitation signal. The magnitude of this leak was chosen so that it fitted the experimental data. These two signals were convolved with a Gaussian impulse response function (IRF) of $500\mathrm{ps}$ FWHM. Photonic noise was added to the signal. The noise amplitude was chosen so that it had the same level as the noise of the experimental data. For each source position and each detector fiber, it corresponds to about 10,000 photons per acquisition (integral of the time-dependent distribution of the signal).

Table 1 shows the impact of the photonic noise on the theoretical accuracy of the $x,y,z$ location of the inclusion. The standard deviation values obtained show a theoretical submillimetric resolution of the system. However, in clinical conditions, prostate tissue heterogeneities, fiber-tissue coupling efficiency, and rectum wall surface conditions may impair the accuracy of reconstruction.

Table 1

Impact of the photonic noise on the theoretical accuracy of the x,y,z location of the inclusion.

This good theoretical resolution can be explained by the high dependence of time of flight on inclusion depth in reflection geometry. For instance, a depth difference of $1\mathrm{mm}$ will lead to a time of flight of $0.04\mathrm{ns}$ , which is compatible with the $25\text{-}\mathrm{ps}$ steps measured with the experimental acquisition chain. As a comparison, intensity measurements (such as those obtained by a continuous wave acquisition system) in a similar geometry would not be capable of achieving a resolution better than $1\mathrm{cm}$ , which is not sufficient for efficient biopsy driving. It can therefore be concluded that time-resolved measurements are required to lower the rate of false negative biopsies, which is an important quality factor for prostate cancer diagnostic.

Probe linearity was tested through several acquisitions and reconstructions of capillary tubes containing various encapsulated ICG concentrations $(0.1–0.5–1.0–2.5–5.0\mu \mathrm{M})$ . The system was able to detect and accurately locate all these inclusions. Table 2 shows the average location and intensity of the reconstructed fluorescence intensity.

Table 2

Average location and intensity of the reconstructed fluorescence intensity.

The reconstructed fluorescence intensity was found to be closely correlated $(R^2=0.94)$ to the capillary tube concentration, as shown in Fig. 5 . This correlation factor reaches $R^2=0.97$ when the $z$ position is fixed at $2.2\mathrm{cm}$ , which shows the influence of the reconstructed depth location on the recovered fluorescence intensity.

Fig. 5

Reconstructed fluorescence intensity as a function of the capillary tube concentration with a depth fixed at $2.2\mathrm{cm}$ .

Figure 6 shows the time-dependent distribution of fluorescence and background signal from the different source–detector indexes (for a $1\text{-}\mu \mathrm{M}$ capillary tube). The ratio between signal and background noise before reconstruction depends on the relative position of the excitation and emission fiber considered. The fluorescence signal decreases exponentially with the source–inclusion–detection distance, whereas the background signal depends only on the distance between source and detector. This explains why the best configuration was obtained for the source 5 and detector 3 [numbering is defined on Fig. 2a] with a signal to background ratio of 93. The least informative channel was the source 3 and detector 2 with a signal to background ratio of 0.2.

Fig. 6

Time-dependent distribution of fluorescence (blue) and background (red) signal from the different source detector pairs (for a $1\text{-}\mu \mathrm{M}$ capillary tube). Source and detector indexes are shown on Fig. 2a. (Color online only.)

Experiments indicated that the current acquisition chain is able to detect the inclusion of $0.1\mu \mathrm{M}$ down to a depth of $2.5\mathrm{cm}$ . To improve this detection limit and to decrease the overall acquisition time, it is planned to replace the current acquisition chain based on the HRI by four photomultiplier tubes connected to a 4-channel time-correlated single-photon counting (TCSPC) chain.

The reconstructed fluorescence map and the ultrasound image obtained with the bimodal auxiliary acquisition system described in Ref. 11 superimposed accurately [Figs. 7a and 7b ], and this gives confidence in our ability to improve the sensitivity of endorectal prostate cancer diagnoses.

Fig. 7

(a) This figure shows a central slice of the prostate phantom in the $xz$ plane given by ultrasounds. This image shows the inclusion, which is more echogenous than the surrounding materials. The darker area under the inclusion corresponds to the shadow cone left by the inclusion. (b) Superimposition of the fluorescence map (in green) obtained after reconstruction on the ultrasound slice (gray scale). The high spatial heterogeneity between water and the phantom creates acoustic noise through multiple scattering known as pulse reverberations. The reverberations produce a tail added to the propagating pulse, and this tail is observed as additional noise at the top of the images. (Color online only.)

4.

Conclusion

An integrated endorectal optical probe based on time-resolved FDOT was developed. It was designed to remain compatible with ultrasound measurements. Thanks to reconstruction based on an analysis of the time-dependent distribution of the fluorescence photons, it was possible to locate an inclusion at fixed depths inside a prostate-mimicking phantom. A $0.1\text{-}\mu \mathrm{M}$ capillary tube was reconstructed at a depth of $2.5\mathrm{cm}$ . The reconstructed fluorescence intensity was found to be closely correlated to the capillary tube concentration. One of the aims of future research will be to obtain better understanding of the origin of the background signal. It will also be necessary to address the problem of reconstructing multiple tumors and the possible presence of heterogeneities in the prostate tissues.