694_Transrectal.prelims 05/04/2002 11 34 am Page i H of ANDBOOK T RANSRECTAL U and LTRASOUND B of the IOPSY P ROSTATE 694_Transrectal.prelims 05/04/2002 11 34 am Page iii H of ANDBOOK T RANSRECTAL U and LTRASOUND B of the IOPSY P ROSTATE Uday Patel,MB ChB,MRCP,FRCR Consultant Uro-radiologist St George’s Hospital and Medical School,London,UK David Rickards MB BS,FFARCS,FRCR Consultant Uro-radiologist University College London Hospitals,London,UK MARTIN DUNITZ CRC Press Taylor & Francis Group 6000 Broken Sound Parkway NW, Suite 300 Boca Raton, FL 33487-2742 © 2002 by Taylor & Francis Group, LLC CRC Press is an imprint of Taylor & Francis Group, an Informa business No claim to original U.S. Government works Version Date: 20130417 International Standard Book Number-13: 978-1-84184-916-4 (eBook - PDF) This book contains information obtained from authentic and highly regarded sources. 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Trademark Notice: Product or corporate names may be trademarks or registered trademarks, and are used only for identification and explanation without intent to infringe. Visit the Taylor & Francis Web site at http://www.taylorandfrancis.com and the CRC Press Web site at http://www.crcpress.com 694_Transrectal.prelims 05/04/2002 11 34 am Page v C ONTENTS Preface vii 1. Transrectal ultrasound – ultrasound physics 1 and equipment 2. Transrectal ultrasound – technique 13 3. Gross and zonal anatomy of the prostate 17 gland,seminal vesicles and ejaculatory ducts 4. Transrectal ultrasound of the normal prostate 25 gland 5. Transrectal ultrasound of the abnormal 35 prostate – common benign conditions 6. Transrectal ultrasound of the abnormal 45 prostate – prostate cancer 7. Transrectal ultrasound biopsy in suspected 57 prostate cancer – principles 8. Transrectal ultrasound biopsy in patients 67 requiring repeat biopsy – principles 9. Transrectal ultrasound biopsy of the prostate – 73 practical aspects 10. Transrectal ultrasound of the abnormal 85 prostate - less common prostate abnormalities 11. Transrectal ultrasound of the seminal vesicles 91 and ejaculatory ducts 12. Transrectal ultrasound-guided seminal vesicle 99 biopsy,ejaculatory duct intervention and cyst drainage 13. Transrectal ultrasound and biopsy after radical 103 prostatectomy 14. Transrectal ultrasound-guided transperineal 111 prostate brachytherapy Appendix A:Patient information sheet given at the 115 (cid:3) time of booking of TRUS biopsy v 694_Transrectal.prelims 05/04/2002 11 34 am Page vi CONTENTS Appendix B:Patient information sheet explaining 117 transrectal ultrasound-guided prostate biopsy, given to patients prior to requesting written consent for the biopsy Bibliography 119 Index 123 vi 694_Transrectal.prelims 05/04/2002 11 34 am Page vii P REFACE The burgeoning interest in prostate diseases and cancer,driven by increasing public awareness as well as advances in treatment,will increase the need for high-quality prostate ultrasound. Satisfying this demand will require a con- siderable service expansion, but it is doubtful whether this can be fulfilled by medical personnel alone, whether urologists or radiologists, and we are sure that paramedics,specialist nurses or sonographers will increasingly be recruited. When any service provision is widened, there is an understandable con- cern about proper training and ensuring that a high standard of excellence is maintained.At the moment there are no agreed guidelines on the minimum training requirements for transrectal ultrasound (TRUS),though some draft documents are under consideration.These emphasise knowledge of ultra- sound physics and equipment, as well as familiarity with the common dis- eases of the prostate. In recognition of these trends this book has been produced.It presents the subject in a simple,logical manner.The underpin- ning fundamentals,such as the physics of ultrasound and equipment details, are presented briefly and pertinently, but most of the book is concerned with the practical aspects of prostate scanning and biopsy.The detail is thor- ough enough that a practitioner will be able to set up and run a safe,accu- rate prostate assessment clinic. Uday PatelMBChBMRCPFRCP David Rickards MBBSFFARCSFRCR vii 694_Transrectal.ch.01 05/04/2002 11 35 am Page 1 T U – 1. RANSRECTAL LTRASOUND U P LTRASOUND HYSICS AND E QUIPMENT Prostate ultrasound has a short history, and its general application only started about 15 years ago although the first experimental transrectal scans were performed in the late 1970s.Viewed now, early medical ultrasound images seem to be barely credible, and it is a testimony to the vision of those early pioneers that they persevered and that we are now able to view the gland with such ease and precision.This chapter expands on the basics of the physics and the current equipment used in transrectal ultrasound. Theoretical principles of medical ultrasound The grey-scale image Diagnostic ultrasound images are formed from the interaction between sound waves in the megahertz range and human tissues.The fundamental physics of sound still applies: the sonic beam is reflected, absorbed and refracted at tissue interfaces as it passes through the body.Of these interac- tions, the most basic is exploited for common ultrasound or grey-scale imaging – the amount of the beam reflected back.The reflected echo is detected by the ultrasound probe, processed to amplify the signal and suppress background noise, and finally assigned a value on a grey scale proportionate to the strength of the returning signal.This, together with positional information, is used to build the familiar grey-scale ultrasound image – an image composed from numerous individual grey points (or pix- els). Reflection is principally dependent on the density gradient presented by the interface. Human organs and tissues are generally of similar densities and provide examples of weak density gradients that reflect hardly any of the sound beam.In contrast,calcium – such as a renal or prostate calculus – presents a dense surface,and because of this high density most of the sound is reflected and hardly any penetrates.The formula for this interaction is 694_Transrectal.ch.01 05/04/2002 11 35 am Page 2 TRANSRECTALULTRASOUND– ULTRASOUNDPHYSICSANDEQUIPMENT given in Box 1.1, and the effects of different interfaces on sound reflection are shown in Table 1.1. Box 1.1 Reflection of sound waves as they pass through human tissues % of beam reflected(cid:2)[Z (cid:3)Z /Z (cid:4)Z ]2(cid:5)100 2 1 2 1 (cid:2) where: Z acoustic impedence of medium 1 1 (cid:2) Z acoustic impedence of medium 2 2 (acoustic impedance(cid:2)density of medium(cid:5)velocity of sound in medium) Table 1.1 Percentage of sonic beam reflected back at different tissue interfaces Interface Percentage of beam reflected Air–soft tissue 99 Bone–soft tissue 30 Fat–soft tissue 1 Urine–soft tissue 0.1 Muscle–soft tissue 0.01 Density gradients within soft tissues and organs like the prostate gland are weak, and the ultrasound image of the prostate gland is therefore rela- tively homogenous. However, modern ultrasound equipment is powerful enough to amplify even weak intra-tissue reflections,and the slightly denser glandularity of the peripheral zone means it is hyperechoic (or brighter) compared to the central tissues. Similarly, the edges of structures such as the urethra and ejaculatory ducts present sharp echo gradients and become sono-visible. The colour Doppler image Sound beams also change in frequency when reflected off a moving surface. This is the Doppler effect, which also accounts for the crescendo/de- crescendo sound of a moving train whistle. In living bodies the red blood cells of arteries and veins present a moving interface,and the change in fre- quency of the sound as it is bounced of the walls of these cells is sufficient to 2 694_Transrectal.ch.01 05/04/2002 11 35 am Page 3 THEORETICALPRINCIPLESOFMEDICALULTRASOUND be detected by the ultrasound probe.From this frequency change the veloc- ity of the moving surface (red blood cells) can be calculated using the simple mathematical formula shown in Box 1.2. Box 1.2 The Doppler effect Sound waves are reflected by a moving interface: (cid:6) (cid:2) (cid:7) f 2FV /V (cos ) 1 2 (cid:6) (cid:2) where: f frequency change (Doppler shift) (cid:2) F frequency of sound emitted by the probe (cid:2) V velocity of blood 1 (cid:2) V velocity of sound 2 (cid:7)(cid:2) cos cosine of angle between sound beam and direction of blood. (Note the dependency on the angle of incidence of the beam. (cid:8) Effectively,at an angle 60°flow may not be detected.) The velocity change is assigned a value on a pre-chosen colour scale, to form a colour Doppler image – sometimes also called the colour velocity image.The most popular scale presents flow towards the probe as red,and away from the probe as blue. Conveniently, arterial flow is generally towards the probe and venous flow away; thus an image is created that is readily assimilated by the observer.An alternative presentation of velocity information is as an absolute velocity and waveform – duplex Doppler.This is useful in the study of large artery haemodynamics,but so far has not been of value in the prostate gland. ‘Power’ Doppler, sometimes also called colour energy imaging, is a fur- ther method of vascular mapping. Its physics is more complex, but essen- tially it is independent of the velocity of blood flow,depicting what may be loosely termed ‘total blood flow’.In the prostate gland either modality can be used interchangeably, but ‘power’ Doppler is very sensitive to artefact and noise. In the prostate gland, power Doppler hasn’t been proven supe- rior to ordinary colour Doppler. 3 694_Transrectal.ch.01 05/04/2002 11 35 am Page 4 TRANSRECTALULTRASOUND– ULTRASOUNDPHYSICSANDEQUIPMENT Equipment for scanning An ultrasound machine has three major parts:the computers housed in the main framework;a display console;and the ultrasound probes.The machine itself is little more than a powerful computerised information processing unit, and the console is not dissimilar to any television or computer moni- tor.The innovative components lie in the probes. Modern ultrasound probes are multiple arrays of solid state electronic units,capable of both sending and receiving the ultrasound beam.However, advances in ultrasound have as much to do with improved computer soft- ware and processing power as with improved probe design.Images are now presented with much better anatomical clarity,by automatic suppression of the noise and sonic clutter that can degrade visibility. Modern ultrasound machines, like computers, have also become much easier to use. Some of the basic handheld systems coming onto the marketplace are not dissimilar to home computers and are as user-friendly. Now, with most machines,all that is necessary is to choose the correct probe and activate the appropriate imaging parameters from a simple user-friendly menu. Nevertheless there is still much scope for individual manipulation and improvement of the image,which may be necessary in patients with big or dense glands. Of the many variables the commonly used ones are given below,but not all machines have the full number of controls available (Fig- ure 1.1). Variables useful for improving the grey-scale image 1. Output power. This is the power of the emitted sound in decibels.The higher the power the stronger is the reflected signal, and the whole image becomes brighter. 2. Receiver gain.This selectively amplifies the returning signal,like the vol- ume control on a hi-fi amplifier.Power and gain often have the same end Figure 1.1 (a) The layout of an ultrasound machine.The main features used for improving the quality of the grey-scale or colour Doppler image are shown.Note that the layout will vary between machines,and not all makes have the full range of controls as shown. (b) Line drawings of a typical grey-scale and colour Doppler image.The main indicators of the chosen image characteristics are shown.Note,however,that the layout will vary according to the make of machine. 4