Acute and chronic kidney failure, which can lead to death if untreated for several days or weeks, is an illness that is as old as humanity itself. In early Rome and later in the Middle Ages, treatments for uremia included the use of hot baths, sweating therapies, bloodletting, and enemas. Current procedures for the treatment of kidney failure include physical processes such as osmosis and diffusion, which are widespread in nature and assist in the transport of water and dissolved substances.
The first scientific descriptions of these procedures dates back to the 19th century and came from the Scottish chemist Thomas Graham, who became known as the “Father of Dialysis.” At first, osmosis and dialysis became popular as methods used in chemical laboratories that allowed the separation of dissolved substances or the removal of water from solutions through semipermeable membranes.
Far ahead of his time, Graham indicated in his work the potential uses of these procedures in medicine. Today hemodialysis describes an extracorporeal procedure, or procedure outside the body, for filtering uremic substances from the blood of patients suffering from kidney disease.
The first historical description of this type of procedure was published in 1913. Abel, Rowntree, and Turner “dialyzed” anesthetized animals by directing their blood outside the body and through tubes of semipermeable membranes made from Collodion, a material based on cellulose. It is impossible to say for sure whether Abel and his colleagues intended to use this procedure to treat kidney failure from the start.
There is no doubt, however, that dialysis treatment today continues to use major elements of Abel’s vividiffusion machine. Before the blood could be routed through the “dialyzer,” its ability to clot or coagulate had to be at least temporarily inhibited. Abel and his colleagues used a substance known as hirudin, which had been identified as the anticoagulant element in the saliva of leeches in 1880.
A German doctor by the name of Georg Haas, from the town of Giessen near Frankfurt am Main, performed the first dialysis treatments involving humans. It is believed that Haas dialyzed the first patient with kidney failure at the University of Giessen in the summer of 1924, after performing preparatory experiments. By 1928, Haas had dialyzed an additional six patients, none of whom survived, likely because of the critical condition of the patients and the insufficient effectiveness of the dialysis treatment. The Haas Dialyzer, which also used a Collodion membrane, was built in a variety of models and sizes.
In fall 1945, Willem Kolff, of the Netherlands, made the breakthrough that had stubbornly eluded Haas. Kolff used a rotating drum kidney he had developed to perform a week-long dialysis treatment on a 67-year-old patient who had been admitted to hospital with acute kidney failure. The patient was subsequently discharged with normal kidney function.
This patient proved that the concept developed by Abel and Haas could be put into practice and thus represented the first major breakthrough in the treatment of patients with kidney disease. The success was partially due to the technical improvements in the actual equipment used for the treatment. Kolff’s rotating drum kidney used membranous tubes made from a new cellulose-based material known as cellophane that was actually used in the packaging of food.
During the treatment, the blood-filled tubes were wrapped around a wooden drum that rotated through an electrolyte solution known as “dialysate.” As the membranous tubes passed through the bath, the laws of physics caused the uremic toxins to pass into this rinsing liquid.
Examples of the Kolff rotating drum kidney crossed the Atlantic and arrived at the Peter Brent Brigham Hospital in Boston, where they underwent a significant technical improvement. The modified machines became known as the Kolff-Brigham artificial kidney, and between 1954 and 1962 were shipped from Boston to 22 hospitals worldwide.
The Kolff-Brigham kidney had previously passed its practical test under extreme conditions during the Korean War. Dialysis treatment succeeded in improving the average survival rate of soldiers suffering from post-traumatic kidney failure and thus won time for additional medical procedures.
One of the most important functions of the natural kidney, in addition to the filtering of uremic toxins, is the removal of excess water. When the kidneys fail, this function must be taken over by the artificial kidney, which is also known as a dialyzer. The procedure by which plasma water from the patient is squeezed through the dialyzer membrane using pressure is termed ultrafiltration.
In 1947, Swede Nils Alwall published a scientific work describing a modified dialyzer that could perform the necessary combination of dialysis and ultrafiltration better than the original Kolff kidney. The cellophane membranes used in this dialyzer could withstand higher pressure because of their positioning between two protective metal grates. All the membranes were in a tightly sealed cylinder so that different pressure ratios could be generated.
By proving that uremic patients could be successfully treated using the artificial kidney, Kolff sparked a flurry of activity around the world to develop improved and more effective dialyzers. The “Parallel Plate Dialyzer” evolved as the most significant development of this period. Rather than pumping the blood through membranous tubes, this dialyzer directed the flow of dialysis solution and blood through alternating layers of membranous material.
Just as the technology of dialyzers continued to develop, so too did the scientific principles regarding the transport of substances across membranes, and these principles were applied specifically to dialysis. This work enabled scientists to develop a quantitative description of the dialysis process and allowed the development of dialyzers with clearly defined characteristics.
Belding Scribner made a breakthrough in this field in 1960 in the United States with the development of what would later become known as the “Scribner shunt.” This new method provided a relatively simple means of accessing a patient’s circulatory system that could be used over a period of several months, meaning patients with chronic kidney disease could, for the first time, be treated with dialysis. The shunt was on a small plate that would be attached to the patient’s body, for example on the arm. One Teflon cannula was surgically implanted in a vein and another in an artery. Outside the body, the cannulae were joined in a circulatory short circuit – hence the name “shunt.” During dialysis, the shunt would be opened and attached to the dialyzer.
Further development brought the introduction in 1962 of improved shunts made entirely from flexible materials. Still, the most decisive breakthrough in the field of vascular access came in 1966 from Michael Brescia and James Cimino. Their work remains fundamentally important to dialysis today. During a surgical procedure, they connected an artery in the arm with a vein. The vein was not normally exposed to high arterial blood pressure and swelled considerably. Needles could then be more easily placed in this vein, which lay beneath the skin, to allow repeated access.
This technique lowered the risk of infection and permitted dialysis treatment over a period of years. The arteriovenous (AV) fistula remains the access of choice for dialysis patients, and some AV fistula implanted more than 30 years ago are still in use today.
This development allowed the long-term treatment of patients with chronic kidney failure. In the spring of 1960, Scribner implanted a shunt in American Clyde Shields, in Seattle. Shields became the first chronic hemodialysis patient, and the dialysis treatments allowed him to live an additional eleven years before dying of cardiac disease. These successes provided a fertile basis for the world’s first-ever chronic hemodialysis program, which was established in Seattle in the following years.
At that time, Scribner and his team refrained from seeking patent protection for many of their inventions and innovations to ensure swift distribution of their life-saving techniques for dialysis patients. The development of improved methods for accessing blood vessels meant that patients with chronic kidney disease could be offered effective treatment for the first time.
However, in the early 1970s, a dialysis treatment lasted around twelve hours and was very expensive, due to the high outlay for materials and the treatment itself. As a result, not all kidney patients could access this life-saving therapy. In the United States, for example, committees decided on how the small number of treatment slots should be allocated – a matter of life-or-death decision-making.
After the early successes in Seattle, hemodialysis established itself as the treatment of choice worldwide for chronic and acute kidney failure. Membranes, dialyzers, and dialysis machines were continuously improved and manufactured industrially in ever-increasing numbers. A major step forward was the development of the first hollow-fiber dialyzer in 1964. This technology replaced the until-then traditional membranous tubes and flat membranes with a number of capillary-sized hollow membranes.
This procedure allowed for the production of dialyzers with a surface area large enough to fulfill the demands of efficient dialysis treatment. Over the years that followed, thanks to the development of appropriate industrial manufacturing technologies, it became possible to produce large numbers of disposable dialyzers at a reasonable price.
Today, dialyzers are made from entirely synthetic polysulfone, a plastic that exhibits exceptionally good filtering efficiency and tolerability for patients. They are still based on these technologies. State-of-the-art dialysis machines also monitor patients to ensure critical conditions can be detected at an early stage and treated. They feature efficient monitoring and data management systems and have become more user-friendly over recent years. A growing number of the latest generation of dialysis machines also utilize computer- controlled machines, online technologies, networking, and special software.