1.

Introduction

Fluid collections occur commonly and can represent several entities comprising seroma, biloma, hematoma, ascites, lymphocele, and abscess, which depend on the localization and cause.^1–4 Depending of the entity of the fluid collection, immediate treatment can be of utmost importance for the patient.^4–10

Computed tomography (CT) is the diagnostic modality of choice in patients with fluid collections to diagnose septic foci and to evaluate the treatment, including the possible percutaneous access.

A common treatment option is CT-guided percutaneous drainage, whereas surgery is only performed in few selected cases nowadays, irresponsive to radiologic-interventional evacuation.^5,8,9

Some CT imaging features have been proposed to be indicative of an infection of a fluid collection, which comprise contrast media enhancement with rim-like appearance, air entrapment, and higher Hounsfield unit (HU) attenuation. However, single imaging features by itself yield not enough specificity and therefore cannot reliably exclude infection.^3,4,11

Texture analysis is a modern quantitative imaging analysis based on radiological images to provide novel imaging biomarkers.^12–14 Most commonly, CT images are employed due to its robust imaging acquisition and high availability in clinical routine.^12–14

In the literature, texture analysis was predominantly investigated in the field of oncological imaging to better characterize tumor behavior and to provide novel applications of imaging to guide oncological patients.¹² Beyond that, CT texture features can provide information regarding the microstructure of tissues, which was shown in preliminary studies.^13–19 This is why texture features might also help to better characterize the content and different aspects of fluid collections to identify fungal associated changes, such as hyphae.

To date, the exact diagnosis of underlying causes pathogens of an infected fluid collection is beyond the scope of imaging and can be provided by microbiological analysis only.²⁰ That is the reason why few systematic data exist to discriminate fungal and bacterial infected fluid collections based upon imaging.²⁰ In clinical routine, it could be of interest to predict the underlying cause, as treatment options differ significantly between fungal and non-fungal fluid collections. Moreover, it could enable a new method to use the radiological images.

Therefore, the present study aimed to elucidate the differences between fungal and non-fungal infected of fluid collections employing CT texture features.

2.

Methods

All patients undergoing CT-guided percutaneous drainage treatment were retrospectively screened in the radiological database of our university hospital between January 2017 and December 2020.

The inclusion criteria of the study:

Finally, 214 patients ($n=76$ females, 35.5%), mean age $62\pm 14$ years, range 20 to 94 years) with 255 overall fluid collections, were included into the present analysis with sufficient imaging and clinical data. The patient sample was previously investigated to evaluate CT texture features for the discrimination between sterile and infected fluid collections.²¹

2.3.

Texture Analysis

The CT images were extracted and further analyzed with the free available software MaZda (version 4.7, available at Ref. 22).^23,24 Only the contrast enhanced CT images in portal-venous phase were used for texture analysis. This was used to reduce heterogeneity of the texture features. The measurements were performed on the largest, representative slide within the boundary of the fluid collection using a polygonal region of interest (ROI). Gas bubbles were excluded of the ROI to reduce possible heterogeneities of the texture features. The radiologist was blinded to the microbiology results. Gray-level normalization was utilized to minimize the influence of contrast and brightness variation, as it is commonly employed in similar studies employing the limitation of dynamics to $\mu \pm 3$ SD ($\mu$ gray level mean, SD standard deviation).²⁵ The extracted features include several first and second order texture features: gray-level histogram, co-occurrence matrix, run-length matrix, absolute gradient, autoregressive model, and wavelet. For every fluid collection, 279 texture features were quantified. Figure 1 displays a representative case of the patient sample with a fungal infected fluid collection for illustrative purposes.

Fig. 1

Representative case of the patient sample with a large fluid collection peritoneally on the left side caused by a fungal infection. (a) The portalvenous phase image with the fluid collection. (b) The ROI is highlighted in red color on the representative slice of the fluid collection.

3.

Results

3.2.

Diagnostic Accuracy of the Investigated Texture Features

Regarding the clinical parameters, age and usage of immunosuppressive drugs were statistically significant different between patients with fungal- and non-fungal infection ($p=$ 0.03 and $p=0.003$, respectively) (Table 1). For conventional imaging findings, only entrapped gas was different between the groups ($p=0.02$).

Only three of the investigated CT texture features were statistically significant different between the groups, namely kurtosis ($p=0.04$), S(3,3)InvDfMom ($p=0.02$), and S(5,-5)DifEntrp ($p=0.003$).

These texture features were further investigated by ROC analysis (Table 2). S(3,3)InvDfMom achieved the highest accuracy with an AUC of 0.62, resulting in a sensitivity of 0.66 and a specificity of 0.57 (Fig. 2).

Table 2

Diagnostic accuracy of the CT texture features to discriminate fungal and non-fungal infected fluid collections.

CT texture feature	AUC	95% CI	Sensitivity	Specificity
Kurtosis	0.59	0.49; 0.70	0.63	0.64
S33InvDfMom	0.62	0.52; 0.71	0.66	0.57
S5minus5DifEntrp	0.59	0.49; 0.69	0.39	0.81

Note: AUC = area under the curve; CI = confidence interval.

Fig. 2

ROC-graph of the statistically significant texture features between fungal and non-fungal infection. The best AUC achieved “S(3,3)InvDfMom” with 0.62 resulting in a sensitivity of 0.63 and a specificity of 0.64.

4.

Discussion

The present study clearly elucidated, whether CT texture analysis can predict the infectious etiology of a fluid collection reliably. This could aid in clinical decision-making, as imaging is performed in clinical routine for treatment planning. In this regard, the antibiotics treatment could be altered, when CT texture analysis is indicating a fungal infection before the microbiological confirmation is provided. In short, this could lead to an earlier treatment of fungal infected fluid collections.

Some CT signs were described to be indicative of an infection of a fluid collection comprising presence of gas entrapment, increased attenuation, encapsulation with or without wall enhancement and fat stranding of the surrounding tissue.^3–6,26 It is a known fact that these imaging findings separately considered cannot reliably predict or exclude an infection of a fluid collection. This was exemplarily shown in a study with 92 patients, reporting a sensitivity of 83.4% and a specificity of 39.3% using the CT signs gas entrapment and high attenuation (20 or greater HU).³

Only a few studies tried to discriminate fungal from bacterial fluid collections as it was not within the scope of CT imaging to provide the underlying cause of inflammation. Hypothetically, bacterial infectious foci should form different microstructural inflammatory tissues compared to fungi.²⁷ Notably, even on the microscopic level, some bacteria can mimic fungal infection.²⁸ Another important point is the formation of mycelium and hyphae, which should result in a different microstructure compared to non-infected and bacterial infection.

A main rationale of the present analysis is that texture features could better characterize fluid collections with the ability to quantify heterogeneities of radiological images.¹² Presumably, different infectious foci should lead to a slightly different CT image, which cannot be diagnosed by the radiologist. This was shown in previous studies in the oncologic field, who could employ texture analysis to reflect histopathologic features of tumors.^15–17 It seems plausible to translate these results to non-oncological disorders.

It is widely acknowledged that higher attenuation of a fluid collection reflects inflammatory debris.^2,3 Haemorrhage can also be the cause of higher attenuation in non-infected or infected fluid collections. Higher CT density over the threshold of 10 HU was the strongest predictor of infected fluid collections, with a good diagnostic accuracy, which was shown in a recent study.²¹

Texture analysis of fluid collections has only been performed in few previous studies.^20,21,29 In a previous study on 320 patients, texture features were not diagnostic superior to conventional imaging findings to discriminate infected from sterile fluid collections.²⁰ However, in this study, bacterial and fungi were not further investigated by subanalysis, which could result in these negative results. Based upon this study, it was further deliberated that different microbiological pathogens might result in different CT texture features. This could lead to a high heterogeneity in the mentioned study to further adjust for the underlying cause of the fluid collection.

In another study collective from Romania, 82 patients with gastric cancer undergoing surgery were investigated.²⁹ The authors of this study could identify 10 texture features, which were statistically significant different between sterile and infected fluid collections, which highlights the possible use of texture analysis but is in distinctive contrast to the other above mentioned study.

Finally, by the same work group, “ATeta3” and “ATeta4” were highlighted as possible texture features to discriminate bacterial from fungi infected fluid collections based upon 42 patients.²⁰

The three identified texture features of the present study were of different groups. The feature kurtosis is a first order histogram parameter, which reflects the slope of the histogram of the HUs.^12,14 The other two parameters, namely S(3,3)InvDfMom and S(5,-5)DifEntrp are second order texture features, which reflect the heterogeneity of the voxels in a higher order and their relationship to each other in a spatial dimension.¹²

A recent study based on 58 patients investigated the diagnostic value of dual-energy spectral CT.³⁰ The authors could identify that monoenergetic images could improve the diagnostic accuracy and showed a higher signal to noise ratio.³⁰ The conclusions drawn of this study were that spectral reconstructions could improve the assessment of infected fluid collections and the help to depict the wall enhancement. However, the quantitative measurements of the spectral reconstructions were not superior compared with measurements in conventional images³⁰ There is definite need to further evaluate the possible benefit of texture analysis derived from dual-energy CT. Other authors elucidated the diagnostic benefit of HUs or clinical scores with mixed results.^31,32

The present study corroborates the abovementioned findings that texture analysis might aid to diagnose the etiology of fluid collections in a non-invasive and time efficient manner. However, the diagnostic overlap identified in the present study is relative large, which could reduce the benefit for clinical routine.

Contrary to the two previous studies of Romania, the present analysis included pleural fluid collections suspicious for empyema and fluid collections in non-surgical patients. This leads to larger patient spectrum, which could also lead to certain heterogeneities. However, the present results can be considered as representative for all fluid collections undergoing CT-guided percutaneous drainage with resulting larger external validity.

Despite the statistically significance of the three identified CT texture features, the clinical significance remains still unknown. The identified AUC is rather low, and the CT texture features on their own might be not be able to reliably predict the infectious status of the fluid collections.

More data are clearly needed to further elucidate the benefit of CT texture analysis in fluid collections.

The present study is not free of limitations. First, it is a retrospective study with inherent known bias. Yet, imaging and microbiology analyses were performed blinded and independently to each other to reduce possible bias. Second, possible selection bias has to be acknowledged, as only treated fluid collections were included. Some small fluid collections might not be treated by this procedure, which could show other associations with texture features. Third, the sample size is rather small and heterogeneous, which could lead to certain bias. A multicentric analysis is needed to further evaluate the diagnostic benefit of CT texture analysis in patients with fluid collections. Fourth, CT texture features are influenced by several technical factors, including contrast media phase, reconstruction algorithm, and CT scanner, which still needs to be addressed.³³ Moreover, a volumetric assessment of the fluid collections including every slice of the CT could provide better results than the present measurement on one CT slice. Yet, it was shown that the single slice measurement has a sufficient interreader agreement.³³ Fifth, there was no adjustment for clinical features, such as age and immunosuppressive drugs, which were statistically significant between the fungal and non-fungal fluid collection group. There might be some bias as no multivariable analysis was performed.

In conclusion, CT texture features could be different between fungal infected and non-fungal infected fluid collections. The diagnostic overlap is large, which could reduce the clinical benefit. Further studies are needed to elucidate the possible diagnostic purpose of CT texture analysis for fluid collections.