Voumed
Acıbadem Maslak Hospital
Acıbadem Maslak Hospital

Acıbadem Maslak Hospital

istanbul

JCI
Specialties
29

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About

Acıbadem Maslak Hospital opened in 2009 and, following a 2018 expansion, now serves across 106,000 square metres on the European side of Istanbul. It has 231 inpatient beds, twenty general operating rooms, three IVF theatres and 51 intensive care beds. Its centres include comprehensive oncology, a breast health and senology institute, an IVF centre, adult and paediatric intensive care, a paediatric clinic and a robotic surgery unit. The hospital holds Joint Commission International accreditation and a LEED Gold green-building certificate, and welcomes international patients with multilingual support.

Specialties

Bariatric and Metabolic SurgeryOrthopedics and TraumatologyPediatricsPhysical Medicine and RehabilitationPlastic and Aesthetic SurgeryPulmonologyHematologyRheumatologyRobotic SurgerySleep DisordersBreast HealthSpine SurgeryThoracic SurgeryCardiology and Cardiovascular SurgeryDermatologyGastrointestinal SurgeryGeneral SurgeryGynecology and ObstetricsUrologyCheck-up and Preventive MedicineDental, Oral and Maxillofacial SurgeryEndocrinology, Diabetes and MetabolismEar, Nose and ThroatGastroenterologyIVF and Reproductive HealthNephrologyNeurology and NeurosurgeryOncologyOphthalmology

Procedures

International patient services

  • International patient office
  • Interpreter and translation services
  • Visa and travel assistance
  • Airport transfer
  • Accommodation assistance

Technologies and equipment

PET-CT

PET-CT is an advanced hybrid imaging method that combines positron emission tomography with computed tomography in a single scan, mapping both the metabolic activity and the anatomical structure of the body at once. A small dose of a radioactive tracer, often a glucose analogue, is injected and gathers in cells that are working harder than normal, which is typical of many tumours. Because it can show where a disease is active before it changes the shape of an organ, PET-CT is one of the most valuable tools for detecting cancer, working out how far it has spread, and checking whether treatment is working.

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SPECT-CT

SPECT-CT is a nuclear medicine imaging method that merges single photon emission computed tomography with computed tomography in one device, capturing both how an organ functions and its anatomical structure in a single session. A low-dose radiopharmaceutical is injected and gathers in the target tissue, where a rotating gamma camera builds three-dimensional functional images while the CT scan defines the exact location within the body. By showing not just the shape of a structure but how active it is, SPECT-CT helps doctors find disease, pinpoint exactly where it sits, and plan treatment with greater confidence.

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EOS 3D Skeletal Imaging

EOS is a low-dose X-ray imaging system that captures the whole spine and the lower limbs in a single pass, while the patient stands naturally and bears their own weight. Two images, one from the front and one from the side, are taken at the same time, and from them the system builds a three-dimensional model of the skeleton. Because it images the body standing, it shows the skeleton in its real, load-bearing posture, which is especially important for assessing the spine and the legs. A key advantage is its very low radiation dose, much lower than standard digital X-ray, with a dedicated mode that reduces exposure even further in children.

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ESWL (Shock Wave Lithotripsy)

ESWL (Extracorporeal Shock Wave Lithotripsy) is a non-surgical way to break up stones in the urinary system, such as kidney and ureter stones, without any incision. High-energy shock waves are generated outside the body and focused precisely onto the stone, shattering it into small fragments that can then pass naturally with the urine. Because nothing is inserted into the body and no cut is made, ESWL is one of the gentlest stone treatments available. It is typically a same-day procedure, after which most people return home and pass the broken fragments over the following days.

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ESWT (Extracorporeal Shock Wave Therapy)

Extracorporeal shock wave therapy (ESWT) is a non-surgical, drug-free treatment that delivers high-energy acoustic waves generated outside the body to a painful or slow-healing tissue. The waves pass harmlessly through the skin and concentrate on the target area, where they stimulate the body's own repair processes. ESWT is used mainly for long-standing tendon, joint and soft-tissue problems that have not responded well to rest, medication or standard physiotherapy. Sessions are short, done in the clinic without anaesthesia, and afterwards most people return straight to their day. It is delivered as part of a rehabilitation plan rather than on its own.

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Ethos Adaptive Radiotherapy

Ethos is an adaptive radiotherapy system that uses artificial intelligence to tailor each cancer treatment to the patient's anatomy on the very day it is delivered. Bodies change a little from session to session: a tumour can shrink, organs shift, the bladder or bowel fill differently. Ethos takes a fresh image at the start of every session, detects these changes and, with AI support, can generate an updated plan in minutes rather than the hours such replanning would normally take, so the dose stays focused on the tumour while better protecting healthy organs.

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Optical Biometry (Myopia Tracking)

Optical biometry is a quick, non-contact diagnostic technology that measures the eye with great precision using a beam of light rather than any physical contact. It is widely used in two situations: to plan eye surgery accurately, by determining the exact power of the artificial lens needed, and to detect and monitor short-sightedness (myopia), especially in children and young adults whose eyes are still growing. In a single, painless scan it records the key dimensions of the eye, providing the precise numbers that guide both surgical planning and long-term follow-up.

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Excimer Laser

The excimer laser is a precise, computer-controlled laser system used to correct refractive errors of the eye, most commonly short-sightedness (myopia), long-sightedness (hyperopia) and astigmatism. It works on the cornea, the clear front surface of the eye, gently removing microscopic layers of tissue to reshape it so that light focuses correctly on the retina. It is the workhorse behind most laser vision correction procedures, where its goal is to reduce or remove a person's dependence on glasses and contact lenses. The treatment is fast, carried out under anaesthetic drops, and recovery is generally quick.

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Scalp Cooling System

A scalp cooling system is a supportive technology that helps reduce hair loss during chemotherapy, one of the side effects patients often find most distressing. The patient wears a snug cap that gently chills the scalp before, during and after the chemotherapy session. Cooling narrows the small blood vessels in the scalp and slows the activity of the hair follicles, so that less of the chemotherapy drug reaches them and they are less affected. For many people, this helps keep more of their own hair through treatment, which can make a meaningful difference to confidence and daily life.

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Femtosecond Laser Cataract Surgery

Femtosecond laser-assisted cataract surgery uses a precise, computer-guided laser to carry out several of the most delicate steps of cataract surgery, the operation that removes the clouded natural lens of the eye and replaces it with a clear artificial one. A cataract is a clouding of the lens that gradually blurs vision, and surgery is the only way to restore clear sight. Instead of using a hand-held blade for the key incisions, the surgeon uses the laser to make them with micron-level accuracy. This added precision can make the procedure gentler and more reproducible while supporting accurate placement of the new lens.

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Photon-Counting CT

Photon-counting CT is a next-generation computed tomography technology with a new kind of detector. Where conventional CT detectors measure the total amount of X-ray energy that arrives, a photon-counting scanner counts each individual X-ray photon and measures its energy. This more refined way of gathering data produces noticeably sharper images with higher contrast, so very small structures, fine blood vessels and early-stage disease can be seen in greater detail, all while keeping the radiation dose low. Like all CT it uses X-rays, but it is designed to make the most of every photon, which can mean better images at a lower dose.

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IVF Electronic Witness System

An IVF electronic witness system is a safety and tracking technology that follows your eggs, sperm and embryos at every step of an in vitro fertilisation cycle, making sure that only your own samples are ever brought together. Each patient's dishes and tubes carry a small electronic tag, and at each laboratory workstation the system automatically reads the tags and confirms they match before any step can continue. If two samples do not belong to the same patient, it sounds an alert and stops the process, providing an extra, automated layer of protection on top of the laboratory team's own careful checks.

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Functional Balance and Coordination System

The functional balance and coordination system is an interactive rehabilitation platform that helps people stand, move and react more steadily. The patient performs guided exercises on a moving platform fitted with smart sensors that track posture and weight shift in real time and show the results on a screen. By reacting to this live feedback, the patient learns to correct posture, sharpen balance and activate the right muscles at the right moment. Because the training is turned into engaging game-like tasks, sessions stay motivating, which encourages the many repetitions that retraining balance requires.

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4D Breast Ultrasound

4D breast ultrasound, also known as automated breast volumetric scanning, is an imaging method that supports the diagnosis of breast cancer. Unlike a hand-held ultrasound, it uses a dedicated probe that moves automatically across the breast to capture the whole organ as a complete three-dimensional volume. It is mainly used alongside mammography, especially for women with dense breast tissue, where a denser background can hide lesions on a standard mammogram. The examination is comfortable, non-invasive and free of ionising radiation, making it a valuable additional layer in breast screening and assessment.

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CO2 Fractional Laser

The CO2 fractional laser is a carbon dioxide skin resurfacing system that delivers energy in thousands of tiny microscopic columns rather than treating the whole surface at once. This fractional pattern leaves healthy skin untouched between each treated point, which speeds healing while the controlled heat triggers collagen and elastin renewal in the deeper layers. The result is smoother texture, firmer skin and a fresher tone, with a recovery that is shorter than older fully ablative lasers. It is one of the most versatile tools in aesthetic dermatology for scars, wrinkles and sun damage.

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DSA Digital Subtraction Angiography

Digital subtraction angiography (DSA) is an advanced imaging method that shows the blood vessels throughout the body in fine detail. A thin catheter delivers a contrast agent into the arteries, and specialised computer processing strips away the surrounding bone and tissue so that only the vessels stand out sharply. It is used to detect vascular problems such as narrowing, aneurysm, malformation and abnormal connections in the brain, abdomen, skin and limbs. DSA is also the basis for many minimally invasive treatments, allowing a specialist to find and, in the same session, treat a vascular problem through a tiny entry point rather than open surgery.

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EBUS Endobronchial Ultrasound

Endobronchial ultrasound (EBUS) is a minimally invasive method that combines bronchoscopy with ultrasound to examine the airways and the tissues and lymph nodes that surround them. A thin, flexible bronchoscope carrying a camera and a small ultrasound probe is passed through the mouth into the airways, where the probe creates real-time images of structures just beyond the airway wall, such as lymph nodes and masses that cannot be seen with a camera alone. Under this live ultrasound guidance, a fine needle can take samples for the laboratory in the same session, all without any surgical incision.

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Prostate Fusion Biopsy (3D Imaging and Navigation)

Prostate fusion biopsy is an advanced way of taking tissue samples from the prostate to diagnose prostate cancer accurately. It blends two types of imaging, a detailed MRI scan taken in advance and live ultrasound during the procedure, into a single three-dimensional picture. This "fusion" lets the doctor see exactly where any suspicious areas lie and guide the biopsy needle straight to them, rather than sampling the gland at random. The result is a more precise, targeted biopsy that improves the detection of cancers that genuinely need treatment, while helping to avoid unnecessary findings.

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EmbryoScope Time-Lapse Incubator

The EmbryoScope is an advanced incubator with a built-in camera, used during in vitro fertilisation to grow embryos and watch their development without ever taking them out of their protected environment. In a standard incubator, embryos must be removed and placed under a microscope to be checked, exposing them briefly to changes in temperature, light and air. The EmbryoScope removes that interruption: it keeps conditions perfectly stable while photographing each embryo at short intervals, building a time-lapse film of its growth that helps the embryology team choose the healthiest embryo to transfer.

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FibroScan

FibroScan is a non-invasive, ultrasound-based device that measures how stiff the liver is, which reflects the degree of scarring, or fibrosis, and at the same time estimates the amount of fat in the liver. It offers a fast, painless alternative to a liver biopsy, with no incision or needle, and it assesses a larger area of the organ than a tiny tissue sample would. A probe is simply placed on the skin over the liver while the patient lies down, and a numerical result is available within minutes. It is widely used to detect and follow liver conditions and to guide and monitor treatment.

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TrueBeam STx

TrueBeam STx is an advanced linear accelerator, a machine that delivers external radiotherapy to treat cancer with very high precision. It shapes powerful radiation beams to match the exact size and shape of a tumour and aims them from many angles, so that a strong dose reaches the target while nearby healthy tissue and organs receive as little as possible. Because it tracks the target and can account for movement such as breathing, it is accurate to within millimetres. This makes it suitable both for conventional, daily radiotherapy and for advanced focused techniques that treat a tumour in only a few sessions. The treatment is non-invasive and painless, with nothing entering the body.

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Da Vinci Robotic Surgery

The da Vinci robotic surgical system lets a surgeon perform complex operations through a few small keyhole incisions instead of one large cut. Sitting at a nearby console, the surgeon controls tiny wristed instruments and a magnified high-definition three-dimensional camera, while the robotic arms translate every hand movement into precise, steady motion inside the body. The system never acts on its own: the surgeon is in full control at all times. For patients, this minimally invasive approach often means less pain, smaller scars, less blood loss and a quicker return to normal life.

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O-Arm

The O-arm is an intraoperative imaging system that rotates a full circle around the patient to produce real-time, high-resolution cross-sectional images while surgery is underway. In effect it brings a mobile CT-style scanner into the operating room, so the surgeon can see the exact position of bone, instruments and implants at the moment they are being placed, rather than relying only on images taken before the operation. It is used mainly in spine, brain and nerve, and orthopaedic trauma surgery, where it gives precise guidance for critical steps and supports greater accuracy and safety.

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3 Tesla MRI

3 Tesla MRI is a high-field magnetic resonance imaging scanner that produces exceptionally detailed pictures of the inside of the body. The "3 Tesla" refers to the strength of its magnet, which is about twice that of a standard MRI scanner, and this extra power allows sharper, higher-resolution images, often in less time. Like all MRI, it uses a strong magnetic field and radio waves rather than X-rays, so there is no ionising radiation involved. It is especially valuable for examining the brain, the nervous system, joints and soft tissues, helping doctors detect and characterise problems that may be hard to see on other scans.

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Whole Body MRI

Whole body MRI examines the entire body in a single session, from the head down to the upper legs and sometimes the feet, producing one connected set of detailed images. It uses a strong magnetic field and radio waves rather than X-rays, so the examination involves no ionising radiation. By covering many organs and regions at once, it offers a broad overview that can pick up disease at an early stage. This makes it useful both as a screening tool for people who want a thorough check and as a way to look at conditions that may affect more than one part of the body.

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Tomosynthesis Mammography (3D Mammography)

Tomosynthesis mammography, often called 3D mammography, is an advanced form of digital mammography that builds a three-dimensional picture of the breast from a series of thin layers. Instead of a single flat image in which overlapping tissue can hide or mimic a problem, it lets the radiologist scroll through the breast slice by slice on a high-resolution screen. This makes small lesions and tumours easier to see and helps distinguish real findings from harmless overlapping tissue, which is especially valuable for screening and for women with dense breasts.

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Endoscopic Ultrasound (EUS)

Endoscopic ultrasound (EUS) combines endoscopy and ultrasound in a single thin instrument, allowing the deeper layers of the digestive tract and the organs and tissues around it to be examined in detail. By placing a tiny ultrasound probe at the tip of an endoscope and guiding it inside the body, very close to the area of interest, it produces highly detailed images of structures such as the pancreas, bile ducts and nearby lymph nodes that can be hard to see from the outside. When needed, a fine needle can take a sample for the laboratory during the same procedure, all without any surgical incision.

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Robotic Arm-Assisted Orthopedic Surgery

Robotic arm-assisted orthopedic surgery is a technology used mainly in knee and hip replacement to plan and carry out the operation with very high accuracy. A detailed three-dimensional plan is built from the patient's own CT scan, and during surgery a robotic arm guides the surgeon's instruments so that bone is prepared and the implant is positioned to that exact plan. The surgeon always holds and directs the instrument; the robotic arm adds steadiness and built-in limits that protect the surrounding tissue. The aim is a joint that fits and balances well, which can mean less pain and a smoother recovery.

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Thulium Laser (ThuLEP)

Thulium laser is a modern surgical laser used mainly to treat an enlarged prostate, a common cause of urinary difficulty in older men. Its best-known use is the ThuLEP technique (Thulium Laser Enucleation of the Prostate), in which the overgrown inner prostate tissue is removed through the urethra with no external cut. A defining feature of the thulium laser is that it penetrates tissue only very shallowly, which allows extremely precise cutting and excellent sealing of small blood vessels as it works. The result is a minimally invasive treatment with little bleeding, a short recovery and durable relief of urinary symptoms.

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Observ 320 Skin Analysis

Observ 320 is a skin imaging and analysis system used in dermatology to look beneath the surface of the skin and assess its type and condition in detail. Using patented LED lighting and a set of filters, it photographs the face under different light modes to reveal features the naked eye cannot see, such as hidden pigmentation, fine lines, congested pores and the network of blood vessels just below the surface. This gives the clinician a clear, objective picture of the skin so that care can be planned precisely and progress tracked over time.

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MR-Linac (MRI-Guided Radiotherapy)

MR-Linac combines a radiotherapy machine with an MRI scanner in a single device, so the radiation oncology team can watch the tumour and the soft tissue around it in real time while treatment is being delivered. Standard radiotherapy relies on planning scans taken on earlier days, but tumours and organs shift slightly from session to session and even with breathing. By seeing the target live, MR-Linac lets the team adapt the plan each day and pause or steer the beam as the tumour moves, delivering a precise dose where it is needed while better protecting healthy tissue.

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Location

Darüşşafaka Mah., Büyükdere Cd. No:40, 34457 Sarıyer/İstanbul

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Accreditations

  • JCI

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