2.1.

NLLS Method

Fluorescence emission involves a transition from the lowest vibrational level of an excited singlet electronic state to any of the vibrational sublevels in the ground state.¹⁵ The emission rate of fluorescence decay is related to the rate of depopulation of the upper-state electrons. The fluorescence dynamics $F\left(t\right)$ as a function of time $t$ is conventionally described by the multiexponential equation¹⁶

In the conventional NLLS method, the estimated parameters ${\alpha }_k$ and ${\tau }_k$ are iteratively adjusted until a best fit between the estimated decay $R_c\left(t_i\right)$ and the experimental decay $R\left(t_i\right)$ is obtained. While a number of nonlinear minimization methods are available, the Marquartdt-Levenberg method is widely used as a benchmark for fitting comparison.^{16, 17} In the curve-fitting procedure, the reduced chi-squared error ${\chi }_r^2$ given by

2.2.

Proposed EM Algorithm with Joint Deconvolution

The EM algorithm is a maximum likelihood estimator that can be applied to parameter estimation of a mixture model.^{18, 19} The advantages of EM have been exploited in many different applications.^{20, 21, 22} It provides an iterative method to simplify the search for maximum likelihood via an expectation step and a maximization step. For our application, we define the probability density function of a normalized observed fluorescence process $g\left(t\right)$ as

Using the EM algorithm, the $\mathbf{\beta }$ and $\mathbf{\tau }$ components of a multicomponent fluorescence decay profile with $N$ total photons can be determined based on Eqs. 6, 7, respectively:

Following parameter estimation, BIC (Ref. 23) is used to determine the optimal number of parameters to represent the given fluorescence decay profile. Its purpose is to reasonably grade the goodness of fit by penalizing the log-likelihood function with the model complexity. The BIC parameter $\lambda$ for the multiexponential model is given by

3.1.

Simulation

To compare the performance of the conventional NLLS and our proposed methods, theoretical lifetime decay profiles with different total photon count, lifetime combination, and contribution factor were generated. A Monte Carlo model was used to simulate biexponential decay profiles in MATLAB^™. The instrumental noise, including the electronic jitter of the TCSPC system and temporal width of laser pulses, was derived from the probability density function of a measured IRF in our measurement system and added to the simulated decay profiles. All simulated decay profiles consist of 3750 data points with temporal resolution of $0.01\mathrm{ns}$ , giving a time span of $37.5\mathrm{ns}$ .

Biexponential decay profiles with widely separated lifetimes of ${\tau }_1=1\mathrm{ns}$ and ${\tau }_2=4\mathrm{ns}$ were first generated at varying contribution factors ( ${\beta }_1=0.1$ , 0.3, 0.5, 0.7, and 0.9) for a total photon count of ${10}^5$ . To evaluate the performance of the methods on closely spaced lifetime parameters, biexponential decay profiles with ${\tau }_1=2\mathrm{ns}$ and ${\tau }_2=4\mathrm{ns}$ were generated at varying contribution factors ( ${\beta }_1=0.1$ , 0.5, and 0.9) for a total photon count of ${10}^5$ . Both methods were also evaluated using decay profiles with low photon counts. The biexponential decays with ${\tau }_1=1\mathrm{ns}$ , ${\tau }_2=4\mathrm{ns}$ , and ${\beta }_1=0.9$ were simulated for total photon counts ranging from $5\times {10}^3$ to ${10}^5$ . In all cases, 10 decay profiles were simulated for each parameter set. To quantify the accuracy of model selection and extracted lifetime parameters for each method, the 10 simulated decay profiles with random noise characteristics from each parameter set were fitted with the NLLS and EM-BIC methods. The model for each simulated decay profile is chosen based on the selection criterion in each method, i.e., a ${\chi }_r^2$ value closest to unity for the NLLS method and the largest BIC parameter $\lambda$ for the EM-BIC method. The model selection for a simulated decay profile is accurate if the chosen value of $m$ matches the true number of lifetime components in the parameter set. The model selection accuracy of each method is determined by taking the ratio of the number of simulated decay profiles that has its model correctly chosen to the total number of simulated decay profiles in a parameter set.

The NLLS method was implemented in MATLAB^™ using the optimization function based on the Marquartdt-Levenberg method. The convergence criterion for the NLLS fitting is chosen to be a least-squares change of less than ${10}^{-8}$ . The EM method was also implemented in MATLAB^™ and the convergence criterion was set to a change in the BIC parameter of less than ${10}^{-8}$ .

3.2.

Experimental Technique

Experimental measurement of the fluorescence lifetime was carried out to verify the simulation study. Two commonly used fluorescent probes for biological studies, fluorescein and acridine orange, were selected owing to their highly overlapped emission spectrum from $500\text{to}650\mathrm{nm}$ . Fluorescein and acridine orange from Sigma Aldrich were dissolved in phosphate-buffered saline (PBS) to stabilize their pH at 7.4. For the measurement of fluorescence lifetime, fluorescein and acridine orange solutions were prepared at concentration of $0.01\mathrm{mM}$ and $50\mu \mathrm{M}$ , respectively.

A pulsed laser diode (LDH400, Picoquant) with an excitation wavelength centered at $400\mathrm{nm}$ was used to excite the fluorophore solutions. The laser diode was biased and pulsed at $20\mathrm{MHz}$ using a laser driver (PDL 800-B, Picoquant). The period of the optical pulse was selected such that it was sufficiently longer than the measured range of fluorescence lifetimes. To minimize the detection of spontaneous emission from the light source, the laser pulses were first transmitted through a $400\text{-}\mathrm{nm}$ bandpass filter before illuminating the samples.

The fluorophore solutions in quartz cuvettes were placed in a right-angled geometry for the lifetime measurement. Fluorescence emission from the solution is directed to a monochromator and detected by a microchannel plate photomultiplier tube (PMT; R3809U-51, Hamamatsu). The fluorescence emission emanating from fluorescein and acridine orange were measured at a wavelength of $520\mathrm{nm}$ . The output current pulses of the PMT were amplified by a wideband preamplifier and converted into fast logic pulses before feeding into a constant fraction discriminator (CFD). The delayed reference pulses from the laser driver and the signal pulses from the CFD were then fed into a time analyzer (PTA 9308, Ortec) to record the photon arrival time. In TCSPC measurement, a single fluorescent photon is detected for every pulsed excitation. By repeating the single-photon-counting process a sufficiently large number of times, a histogram of photon arrival times was constructed to reveal the characteristic exponential decay of the fluorescence emission.²⁴ The IRF of the measurement system was determined by measuring the excitation photon at $400\mathrm{nm}$ from a scattering suspension of Ludox colloidal silica (Sigma-Aldrich).

4.1.

Simulation

The same initial guess values of the decay parameters $\mathbf{\beta }$ and $\mathbf{\tau }$ were used for both methods. All simulated decay profiles were fitted for lifetime component number $m$ of 1 to 4. In the NLLS method, the simulated biexponential decay profiles were fitted to Eq. 2 and the respective contribution factors were calculated based on Eq. 5. The optimal lifetime component number is obtained when ${\chi }_r^2$ is closest to unity. For the proposed EM-BIC method, Eqs. 6, 7, 8, 9, 10, 11, 12 were used to deduce the decay parameters. The best-fitting results are selected based on the largest $\lambda$ value. The typical results of the fitting procedure and model selection using the NLLS and EM-BIC methods are illustrated in Tables 1, 2 , respectively. The simulated decay profile consists of $1\times {10}^5$ photons originating from two fluorescent components ( ${\tau }_1=1\mathrm{ns}$ and ${\tau }_2=4\mathrm{ns}$ ) with equal contribution factors. In this example, the lifetime component number was erroneously determined as $m=4$ by the NLLS method, while the EM-BIC method correctly determines the lifetime component number.

Table 1

Fluorescence lifetime parameters extracted from the biexponential decay profile simulated with τ1=1ns , τ2=4ns , and β1=0.5 using conventional NLLS method.

Table 2

Fluorescence lifetime parameters extracted from the bi-exponential decay profile simulated with τ1=1ns , τ2=4ns , and β1=0.5 using the EM-BIC method.

In the first study, we investigate the performance of the EM-BIC method on the simulated decay profiles comprising two fluorescent components with widely separated fluorescence lifetimes ( ${\tau }_1=1\mathrm{ns}$ and ${\tau }_2=4\mathrm{ns}$ ) and having a sufficiently large photon counts of $1\times {10}^5$ . Using these data, the two methods were compared for values of ${\beta }_1$ ranging from 0.1 to 0.9. The parameters predicted at a lifetime component number of $m=2$ are shown in Tables 3, 4 . Ten decay profiles were generated for each parameter set and fitted with each method to determine the corresponding mean and standard deviation of the extracted lifetimes. The model selection accuracy for each method is calculated from the proportion of the 10 simulated decay profiles for each parameter set that has its component number $m$ correctly determined by the model. The biexponential lifetime values and model selection accuracy determined from both methods are also plotted in Fig. 1 for comparison.

Fig. 1

Biexponential fluorescence lifetime values (–●–,–◼–) extracted from decay profiles simulated with widely separated lifetimes of ${\tau }_1=1\mathrm{ns}$ and ${\tau }_2=4\mathrm{ns}$ (dashed lines), and a photon count of $1\times {10}^5$ using (a) the conventional NLLS method and (b) the EM-BIC method. The model selection accuracy (–▲–) specifies the proportion of 10 decay profiles simulated for each parameter set that has its component number $m$ correctly determined by a model.

Table 3

Biexponential lifetime parameters extracted from decay profiles simulated with widely separated lifetimes ( τ1=1ns , τ2=4ns , and 1×105 photons) using the conventional NLLS method.

Table 4

Biexponential lifetime parameters extracted from decay profiles simulated with widely separated lifetimes ( τ1=1ns , τ2=4ns , and 1×105 photons) using the EM-BIC method.

The results show that the simulated decay profiles were fitted equally well with $m=2$ using both methods. However, there is a noticeable spread in the value of ${\tau }_1$ extracted with the NLLS method for ${\beta }_1=0.1$ . Similarly, we can see that the standard deviation of the estimated ${\tau }_2$ increases with ${\beta }_1$ for both fitting methods. This is attributed to the reduced photon number from the lifetime component whose fractional contribution is decreased, which resulted in a poorer estimate of the respective lifetime value. In particular, we note from Fig. 1 that the deviation is less significant when the EM-BIC method is used. As seen in Fig. 1a, the conventional NLLS method exhibits a decreasing accuracy in model selection for low values of ${\beta }_1$ even though the fluorescence lifetimes were relatively well estimated at $m=2$ . The NLLS method only correctly identifies the lifetime component number in 1 out of the 10 decay profiles (10%) simulated for the parameter set with ${\beta }_1=0.3$ . By contrast the EM-BIC method succeeds in selecting the correct lifetime component number for all the simulated decay profiles, as depicted in Fig. 1b. The results clearly indicate that the EM-BIC method outperforms the conventional NLLS method in determining the correct number of fluorescent components.

The next simulation study compares the two methods using decay profiles simulated with closely spaced lifetimes ( ${\tau }_1=2\mathrm{ns}$ and ${\tau }_2=4\mathrm{ns}$ ), a sufficiently large photon count of $1\times {10}^5$ and ${\beta }_1$ values of 0.1, 0.5, and 0.9. The lifetime values and model selection accuracy determined from the conventional NLLS method and our EM-BIC method are given in Tables 5, 6 , respectively. The results are also plotted in Fig. 2 for comparison. The average biexponential lifetimes predicted by both methods are in good agreement with the true values. However, the extracted lifetime value of the component that has a reduced photon count, i.e., a lower $\beta$ value, exhibits an increased standard deviation. The model selection accuracy also drops drastically with the use of the ${\chi }_r^2$ to resolve the two closely separated fluorescence lifetime components, with a maximum accuracy of only 40% for ${\beta }_1=0.1$ [Fig. 2a].

Fig. 2

Biexponential fluorescence lifetime values (–●–,–◼–) extracted from decay profiles simulated with closely spaced lifetimes of ${\tau }_1=2\mathrm{ns}$ and ${\tau }_2=4\mathrm{ns}$ (dashed lines), and a photon count of $1\times {10}^5$ using (a) the conventional NLLS method and (b) the EM-BIC method. The model selection accuracy (–▲–) specifies the proportion of 10 decay profiles simulated for each parameter set that has its component number $m$ correctly determined by a model.

Table 5

Fluorescence lifetime parameters extracted from the decay profiles simulated with closely spaced lifetimes ( τ1=2ns , τ2=4ns , and 1×105 photons) using the conventional NLLS method.

Table 6

Fluorescence lifetime parameters extracted from decay profiles simulated with closely spaced lifetimes ( τ1=2ns , τ2=4ns , and 1×105 photons) using the EM-BIC method.

Last, we compare the performance of the conventional NLLS and our EM-BIC methods with varying total photon count in the simulated biexponential decay profile. Widely separated lifetime components with ${\tau }_1=1\mathrm{ns}$ and ${\tau }_2=4\mathrm{ns}$ were used to generate the decay profiles for various total photon count. The value of ${\beta }_1$ is set at 0.9 such that the simulated decay profiles are dominated by the shorter lifetime component. As shown in Tables 7, 8 , the shorter lifetime component ${\tau }_1$ was accurately extracted by both methods even at a very low photon count of $9\times {10}^3$ . By contrast, the extracted value of ${\tau }_2$ is less accurate and deviates significantly from the true value when the NLLS method is used. As depicted in Fig. 3a, the NLLS method gave a poor estimation of ${\tau }_2$ ranging from $3.01\text{to}4.73\mathrm{ns}$ for a total photon count of $1\times {10}^4$ . When the total photon count reduces to $5\times {10}^3$ , the uncertainty in ${\tau }_2$ becomes even larger and the estimate of ${\tau }_2$ ranges between 1.95 and $6.13\mathrm{ns}$ . At the lowest total photon count, the NLLS method was also unable to correctly determine the lifetime component number in any of the simulated decay profiles. By comparison, the EM-BIC method was able to determine the correct lifetime component number and the extracted lifetime values are reasonably close to the true values [see Table 8 and Fig. 3b].

Fig. 3

Biexponential fluorescence lifetime values (–●–,–◼–) extracted from decay profiles simulated with widely separated lifetimes of ${\tau }_1=1\mathrm{ns}$ and ${\tau }_2=4\mathrm{ns}$ (dashed lines), and ${\beta }_1=0.9$ using (a) the conventional NLLS method and (b) the EM-BIC method. The model selection accuracy (–▲–) specifies the proportion of 10 decay profiles simulated for each parameter set that has its component number $m$ correctly determined by a model.

Table 7

Fluorescence lifetime parameters extracted from decay profiles simulated with varying total photon count ( τ1=1ns , τ2=4ns , and β1=0.9 ) using the conventional NLLS method.

Table 8

Fluorescence lifetime parameters extracted from decay profiles simulated with varying total photon count ( τ1=1ns , τ2=4ns , and β1=0.9 ) using the EM-BIC method.

4.2.

Experiment

The measured IRF and lifetime decay profiles of fluorescein and acridine orange for a total photon count of $2\times {10}^5$ are shown in Fig. 4 . The full width at half maximum (FWHM) of the measured IRF is $86\mathrm{ps}$ . We can see from Fig. 4 that the fluorescence lifetime of fluorescein is longer than that of acridine orange. Using the NLLS method, the fluorescence lifetime of acridine orange is determined to be $1.84\mathrm{ns}$ with a ${\chi }_r^2$ of 1.03, while the estimated lifetime of fluorescein is $4.18\mathrm{ns}$ with a ${\chi }_r^2$ of 1.09. The extracted lifetime values are in good agreement with the values reported in the literature²⁵ and those from EM-BIC analysis.

Fig. 4

Normalized plots of (a) the system IRF, (b) the fluorescence decay of acridine orange, and (c) the fluorescence decay of fluorescein measured with a total photon count of $2\times {10}^5$ .

Three biexponential decay profiles (A to C) with varying contributions from fluorescein and acridine orange were chosen to compare the performance and accuracy of the NLLS and EM-BIC methods. The respective contribution factors from each component and the total photon count are listed in Table 9 . The first biexponential decay profile A comprises fluorescence measured from the two fluorophores with equal contribution factors. Decay profile B is dominated by fluorescein, whereas decay profile C has a dominant contribution from acridine orange.

Table 9

Fractional contribution and total photon count of the experimental biexponential decay profiles of fluorescein and acridine orange.

The same initial guess values of the decay parameters $\mathbf{\beta }$ and $\mathbf{\tau }$ were used for both methods. All decay profiles were evaluated with each method using lifetime component numbers 1 to 3. The results of the parameter extraction and model selection using the NLLS and EM-BIC methods are shown in Tables 10, 11 , respectively. A comparison between the true lifetime parameters of each experimental decay profile and those determined from both methods with $m=2$ are also shown in Fig. 5 .

Fig. 5

Fluorescence lifetime parameters of experimental decay profiles (a) A, (b) B, and (c) C extracted using the conventional NLLS method (◼) and the EM-BIC method (△). The true fluorescence lifetime parameters (×) are also plotted for comparison.

Table 10

Fluorescence lifetime parameters extracted from the experimental biexponential decay profiles using the conventional NLLS method.

Table 11

Fluorescence lifetime parameters extracted from the experimental biexponential decay profiles using the EM-BIC method.

The fitting results of profile A for both methods predicted a lifetime component number of $m=2$ , indicating the presence of two fluorescent components. The extracted lifetimes from both methods are in excellent agreement with the true lifetime parameters of profile A [Fig. 5a]. The goodness of fit for both methods becomes degraded at $m=3$ , although the corresponding fluorescence lifetimes are still reasonably close to the true values. For decay profile B, a lifetime component number of $m=3$ is predicted with the NLLS method. The value of ${\tau }_1(={\tau }_2=2.78\mathrm{ns})$ extracted from the NLLS method is obviously different from the true values. In contrast, the EM-BIC method predicted the correct lifetime component number of 2, with extracted lifetime values that are in good agreement with the true values, as shown in Fig. 5b. The NLLS analysis of profile C underestimated the lifetime values despite selecting the correct lifetime component number. On the other hand, the EM-BIC method accurately predicted the correct values for profile C [Fig. 5c].