RU2361520C1 - Method of differentia diagnostics of prostate gland cancer - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to field of medicine, namely, to urology. Laser Doppler ultrasonography, in which probe-sensor is installed in point of prostate gland projection perpendicular to perineum skin. Dopplerogram is decomposed into harmonic constituents, index of microcirculation (I) is calculated by formula:

, where M is index of microcirculation in perfusion units, α - mean-square deviation, A_max - maximal amplitude in each group of fluctuations of amplitude-frequency spectrum; F_max - maximal frequency in each group of fluctuations; α - slow rhythms 1-3 cycles per a minute, LF - slow rhythms 4-12 cycles a minute, HF - fast rhythms 12-36 per minute; CF - pulse fluctuations. If microcirculation index is less than 0.433 malignant neoplasm of prostate gland is diagnosed, if index of microcirculation is larger than 0.433, benign hyperplasia is diagnosed.

EFFECT: extension of arsenal of means for differential diagnostics of prostate gland cancer.

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Description

The invention relates to medicine, namely to urology, and can be used for non-invasive differentiation of prostate cancer from benign hyperplasia.

Prostate cancer (PCa) has high medical and social significance, which is associated with the severity of this disease and a significant spread of PCa in older men.

According to statistical studies, prostate cancer is the most common tumor of the urogenital system, accounting for 15-20% of malignant neoplasms in men older than 50 years and occupying the third place in the structure of malignant neoplasms after stomach cancer and lung cancer.

The relevance of the diagnosis of prostate cancer is caused not only by the variability of the clinical manifestations of the disease and severe secondary changes in the urogenital system and pelvic organs, but also by the difficulty of differential diagnosis, especially in the early stages of prostate cancer. Due to the absence of early symptoms, prostate cancer is recognized, as a rule, at the stage of generalization of the process, when surgical interventions are contraindicated, and with the help of hormonal drugs, cytostatics and radiation therapy, a long-term therapeutic effect cannot be achieved.

A known method for the diagnosis of prostate cancer by digital rectal examination of the prostate gland.

However, the known method is inaccurate, since it can only be used to determine a tumor node 1.5-2.0 cm in size if it is localized in one of the lateral lobes of the prostate. In this regard, 70% of tumors are not palpable [McNeal J.E., Kindrachuk R.A., Freiha F.S., Bostwick D.G., Redwine D.G., Stamey T.A. Patterns of progression in prostate cancer. - Lancet. - 1989. - C.60].

A known method for the diagnosis of prostate cancer by measuring the level of prostate-specific antigen (PSA) blood. The PSA level as a diagnostic test is characterized by sensitivity according to different authors on average about 60% and a specificity of 90% for PSA> 4 ng / ml. The normal PSA content was considered to be less than 4 ng / ml, recently less than 2.5 ng / ml.

However, PSA is not specific for prostate cancer, since its level rises with prostate adenoma, prostatitis, and after various transurethral interventions. Diagnosis of the last two reasons for increasing PSA levels is not difficult, which cannot be said about the differential diagnosis of adenoma and prostate cancer [Matveev BP, Bukharkin BV, Matveev VB, “Prostate cancer, M., 1999 . - S.21-45].

The closest in technical essence and the achieved positive result is a method for the diagnosis of prostate diseases using transrectal ultrasound, including a subjective visual assessment of blood circulation in the prostate according to color Doppler mapping [Clinical Guide to Ultrasound Diagnostics. / Ed. V.V.Mitkova. T.1. - M .: Vidar, 1996. -

S.273-297], adopted as a prototype.

The disadvantages of this method are:

1. Low accuracy due to the lack of clear quantitative differential diagnostic criteria for blood circulation of the prostate gland with its various pathologies;

2. The subjectivity of the perception of the resulting picture of blood circulation of the prostate;

3. The relative inconvenience of the patient in the preparation and conduct of the examination procedure.

The technical result of the proposed method is to increase the accuracy of the differential diagnosis of prostate cancer.

The technical result of the proposed method for the differential diagnosis of cancer and benign prostatic hyperplasia is achieved due to clear quantitative differential diagnostic criteria used in the proposed method.

The authors propose a non-invasive method for differential diagnosis of prostate cancer by measuring microcirculation of the prostate using laser Doppler flowmetry (LDF).

The method is as follows.

To assess microcirculation by the LDF method, the LAKK-01 apparatus (NPP LAZMA, Russia) is used, which consists of an emitter, a photodetector, and light-guide probes-sensors, which include three optical fibers enclosed in a general light-tight harness. In this case, laser radiation with a wavelength of 0.63 μm is transmitted through one fiber to the surface under investigation, and radiation reflected from the surface under investigation is received through two other fibers. A helium-neon laser of the type LGN-207B or LGN-208B with a wavelength of 0.63 microns is used as an emitter. The laser radiation power at the input of the light guide cable is at least 0.5 mW. To study the microcirculation of the prostate gland, a projection point of the prostate is chosen, which is located at the same distance between the anus and the scrotum along the midline (perineal suture). The probe sensor during recording LDF is installed at the projection point of the prostate gland perpendicular to the skin of the perineum. One of the conditions of the procedure is to find the patient in a warm room in a relaxed state, which eliminates errors when recording Dopplerograms associated with excessive muscle contractions when feeling cold, either lying on your back with bent knees, or on a gynecological chair. The recording time is 2 minutes.

The Dopplerogram is laid out on harmonic components with different frequencies and the contribution of the amplitude of each of these components to the total signal is quantified. Each rhythmic component in the spectral analysis of an LDF-gram is characterized by two parameters: frequency - F and amplitude - A. There are five main frequency ranges in which the vessel wall is modulated during the functioning of the regulation mechanisms.

1. Slow rhythms (LF - low frequency), the frequency of 1-10 oscillations per minute, are associated with the intrinsic activity of the components of the microvasculature, normally the prevailing rhythms. In turn, slow rhythms are divided into three groups:

- α - 1-3 cycles per minute, due to the secretory activity of the capillary endothelium;

- β - 4-8 cycles per minute, neurogenic fluctuations associated with sympathoadrenal effect on smooth muscles;

- λ - 9-12 cycles per minute, myogenic rhythms associated with the activity of myocytes by the pacemaker mechanism.

Using software, α-rhythms were calculated and designated as LF-rhythms consisting of β- and λ-rhythms.

2. Fast rhythms (HF - high frequency), frequency 12-36 per minute, are characterized by respiratory waves.

3. Pulse oscillations (CF - cardiodependet frequency) - cardiac rhythms, the frequency corresponds to heart rate, is associated with conducting a pulse wave to the microvasculature.

Using software, laser Doppler flowmetry (LDF) curves are processed and the main indicators are found.

The obtained indicators were analyzed and the microcirculation index was calculated:

where And is the microcirculation index, which shows the relationship of the microcirculation index with the frequency-amplitude spectrum (i.e., the relationship of the microcirculation index with the main components of the fluctuations of the vascular wall);

M is the microcirculation index, which characterizes the flow of red blood cells per unit time through a unit volume of tissue and is measured in relative or perfusion units (perf. Units);

σ is the standard deviation (RMS), which characterizes the statistically significant fluctuations in the speed of red blood cells;

A _max - the maximum amplitude in each group of oscillations of the amplitude-frequency spectrum;

F _max - the maximum frequency in each group of oscillations;

α - slow rhythms 1-3 cycles per minute, due to the secretory activity of the capillary endothelium;

LF - slow rhythms of 4-12 cycles per minute, consisting of β- and λ-rhythms, are associated with neurogenic and grave vibrations;

HF - fast rhythms, the frequency of which is 12-36 per minute, characterized by respiratory waves;

CF - pulse fluctuations - cardiac rhythms, the frequency corresponds to heart rate, is associated with conducting a pulse wave to the microvasculature.

The regularity of the distribution of the microcirculation index from the type of pathology of the prostate is clearly defined. The boundary value is the value of the microcirculation index, equal to 0.433 units. The microcirculation index is less than 0.433 units. indicates a high probability of malignant neoplasms of the prostate, and, conversely, a microcirculation index of more than 0.433 units. indicates the presence of benign hyperplasia. The sensitivity and specificity of this technique were 93 and 88%, respectively, which exceeds the sensitivity and specificity of previously known methods for diagnosing prostate cancer.

Clinical example No. 1.

Patient Sartin A.I., 75 years old. Case history No. 2448. Referred with a diagnosis of Susp: c-r prostate. The clinical picture was dominated by complaints of frequent urination with a sluggish stream, nocturia up to 4 times.

With a digital rectal examination, the prostate gland is 4x4 cm, smooth, of dense consistency, the interlobar sulcus is smooth, the nodes are not palpated. The level of total blood PSA was 12.5 ng / ml. By TRASIS of the prostate: an increase in the volume of the prostate gland - 80.37 cm ³ , a node of transient zones with cyst formation and moderately increased vascularization.

The patient was examined by the LDF method. Got the following results:

M = 3.66, σ = 0.67, A _maxα = 1.65, A _maxLF = 1.57, A _maxHF = 0.99, A _maxCF = 0.34, F _maxα = 2.40,

F _maxLF = 3.60, F _maxHF = 12.60, F _maxCF = 58.80.

According to the formula, the microcirculation index was calculated, which amounted to 0.434. A diagnosis was made of benign prostatic hyperplasia, which was confirmed histologically (adenomatous prostatic hyperplasia).

Clinical example No. 2.

Patient Monoshin V.F., 70 years old. Case history No. 2980. Referred with a diagnosis of Susp: c-r prostate. The clinical picture was dominated by complaints of frequent urination with a sluggish stream, nocturia up to 4 times.

With a digital rectal examination, the prostate gland is 3 × 3.5 cm, smooth, of dense consistency, the interlobar groove is smooth, the nodes are not palpated. The level of total blood PSA was 10.9 ng / ml. According to TRUS of the prostate: an increase in the volume of the prostate gland - 63.72 cm ³ , diffuse-heterogeneous changes in the structure of the prostate, vascularization is normal.

The patient was examined by the LDF method. Got the following results:

M = 4.84, σ = 2.19, A _maxα = 3.96, A _maxLF = 3.91, A _maxHF = 3.52, A _maxCF = 1.02, F _maxα = 2.40,

F _maxLF = 3.60, F _maxHF = 15.00, F _maxCF = 51.60.

According to the formula, the microcirculation index was calculated, which amounted to 0.382. Based on the data obtained, confirmed by biopsy (histological diagnosis No. 14499-503 - clear cell adenocarcinoma) was diagnosed with C-r prostate T2N0Mx.

Thus, the claimed method allows to increase the accuracy of the differential diagnosis of cancer and benign prostatic hyperplasia by applying clear quantitative differential diagnostic criteria for assessing microcirculation of the prostate using laser Doppler flowmetry, reducing subjective assessment. The advantage of the proposed method is its non-invasiveness. The inventive method is effective and technically just applicable.

Claims (1)

A method for differential diagnosis of prostate cancer, including microcirculation research, characterized in that laser Doppler flowmetry is performed, in which a probe sensor is installed at the projection point of the prostate gland perpendicular to the perineal skin, the Dopplergram is laid out on harmonic components, and the microcirculation index (I) is calculated by the formula:

,
where M is the indicator of microcirculation in perfusion units;
α is the standard deviation;
And _max is the maximum amplitude in each group of oscillations of the amplitude-frequency spectrum;
F _max - the maximum frequency in each group of oscillations;
α - slow rhythms 1-3 cycles per minute;
LF - slow rhythms 4-12 cycles per minute;
HF - fast rhythms 12-36 per minute;
CF - pulse fluctuations;
and with a microcirculation index of less than 0.433, a malignant neoplasm of the prostate is diagnosed, and with a microcirculation index of more than 0.433, benign hyperplasia is diagnosed.