Dialysis, by Kyle Reed

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Figure 1. Diagram of a nephron and the processes [1]

The human kidney is an essential organ, playing vital roles in both the urinary and endocrine system. The kidney maintains the chemical and water balance of the body with the help of nephrons, which are the functioning units that remove waste from the blood. Nephrons accomplish this through filtration and both active and passive transport; each kidney has approximately 1 million nephrons. Figure 1 shows a nephron and the processes that occur [1][2][3].

It is important to note that the blood enters the nephron at the glomerulus, which filtrates solutes up to 60,000 Da. The glomerular filtration rate (GFR) for an average person is roughly 125 mL/min, or 180 liters/day. The resulting fluid and solutes then enter the renal tubes, where different types of transport occurs [1][2].

In the proximal tube (first part of the renal tube), water is reabsorbed back in the blood stream: around 178 liters/day. Other substances are also reabsorbed, such as sodium and glucose. Glucose is always fully recovered while sodium is regulated; depending on the salt concentration within the body, sodium is either reabsorbed or secreted [1].

The substances that were not filtered out in the glomerulus, like hydrogen and potassium ions, ammonia, and certain drugs, enter the peritubular capillaries. These components are then secreted into the distal tubule (second part of the renal tube). The toxins are then sent to the bladder with the ~1% of water that wasn't reabsorbed [1].

The kidney also has other important functions by sensing the composition of the blood and secreting substances that aid in bone metabolism, red blood cell production, and blood pressure regulation. When kidneys are no longer able to function as intended, renal failure occurs and can be classified as acute or chronic. Both can be treated with dialysis if there is not a donor organ available [2].


Figure 2. Willem Johan Kolff (1911-2009) [5]
Figure 3. Kolff's first dialysis machine on a Dutch stamp [6]

1854 - Thomas Graham developed an apparatus that held urine and water separated with a membrane. After several hours, sodium chloride and urea were found to have transported across the membrane. Set the basis for dialysis. [4]

1924 - Georg Haas performed first human hemodialysis on a uremic patient. [4]

1937 - First flat hemodialysis membrane made of cellophane produced. [4]

1940 - Willem Kolff take interest in acute renal failure. [4]

1943 - Kolff created dialysis machine using sausage casings, washing machine, and orange juice cans. Treated 15 patients with little to no success. [4][5][6][7]

1945 - Kolff treated a 67 year old woman with longer dialysis time and she survived for another seven more years. [5]

1947 - Kolff donates his dialysis machines to other hospitals, allowing other doctors to learn the design of the machine and improve upon it. [5][7]

1948 - First hermodialysis machine constructed in the US to be used at Peter Bent Brigham Hospital. [5]

1954 - First kidney transplant. [7]

1960 - Belding Hibbard Scribner invented the Scribner shunt, preventing the numerous incisions required for dialysis. [7]

1962 - Scribner opened the first outpatient dialysis facility. [7]

Current Technology

There are two types of dialysis used to treat kidney renal failure, hemodialysis and peritoneal dialysis. Hemodialysis is performed on about 85% of patients, with the remainder being peritoneal dialysis [2].


Figure 4. Hemodialysis [8]

Peritoneal Dialysis

Figure 5. Peritoneal Dialysis [9]

Future of Dialysis

Figure 7. As of January 2013 [13]
Figure 6. Artifical Kidney by USCF [12]

Nephron Regeneration

Human nephrons can only regenerate partially; they are not able to grow new ones. Fish are able to grow new nephrons however, and zebrafish have been extensively studied in order to try and emulate their kidney cells ability to self-replicate. Research has found that the zebrafish kidneys probably contains self-renewing nephron stem/progenitor cells. Future research into this field can allow scientists to try and replicate the growing of new nephrons in humans [10].

Artificial Kidney

There has been long debate about whether the technology would be created that will allow humans to bypass dialysis and "wear" a artificial kidney that is cheap in the near future [11]. The University of California, San Francisco (USCF) is looking to end that debate as soon as possible. They were able to create an artificial kidney that requires no power source and is projected to be equal or less in cost then a kidney transplant. It will have an operational lifetime of around a decade; it can filter blood and respond to some chemicals in the system with feedback. The first clinical trials for this device are planned for 2017, and the device itself is on a accelerated track for FDA approval [12]. (See source for video on the device).


It is apparent that the both of the research approaches described above can have a drastic impact on the lives of those that require dialysis. Whether it be allowing them to regrow an entire kidney, or have an artificial one instead, it would allow people to live their lives without the worries of having to spend countless hours near a dialysis machine to survive. However, these technologies could prove to be even more important for those that are not even able to have dialysis due to financial restrictions.

Figure 6 shows the global market for dialysis as of January 2013. The "Rest of World" portion has been amplified with the growing market in India. Currently, there are 52,000 Indian patients on dialysis, but this is no where near the amount of people that require it. While dialysis in India costs 4 to 33 percent of the cost in the U.S., more then 90 percent of the 230,000 that develop chronic kidney failure each year are unable to acquire treatment [13].


[1] Space Biomedical Research Institute. http://home.bway.net/rjnoonan/humans_in_space/fluid.html (accessed February 6, 2013).

[2] Ratner, B.D.; Hoffman, A.S.; Schoen, F.J.; Lemons, J.E. Biomaterials Science: An Introduction to Materials in Medicine, 2nd ed.; Elsevier Academic Press: San Diego, 2004; pp. 514-518.

[3] Saltzman, W. Tissue Engineering: Principles for the Design of Replacement Organs and Tissues; Oxford: New York, 2004; pp. 387-391.

[4] Advanced Renal Education Program. http://www.advancedrenaleducation.com/Hemodialysis/HistoryofHemodialysis/tabid/177/Default.aspx (accessed February 6, 2013).

[5] The Kidney Doctor. http://www.thekidneydoctor.org/2012/02/remembering-willem-kolff.html (accessed February 6, 2013).

[6] $100 Dialysis. http://100dialysis.wordpress.com/2012/01/24/a-brave-beginning/ (accessed February 6, 2013).

[7] DaVita. http://www.davita.com/kidney-disease/dialysis/motivational/the-history-of-dialysis/e/197 (accessed February 6, 2013).

[8] VascularWeb. http://www.vascularweb.org/vascularhealth/Pages/dialysis-access.aspx (accessed February 6, 2013).

[9] National Kidney and Urologic Diseases Information Clearinghouse. http://kidney.niddk.nih.gov/kudiseases/pubs/peritoneal/

[10] Diep, C.Q.; Ma, D.; Deo, R.C.; Holm, T.M.; Naylor, R.W.; Arora, N.; Wingert, R.A.; Bollig, F.; Djordjevic, G.; Lichman, B.; Zhu, H.; Ikenaga, T.; Ono, F.; Englert, C.; Cowan, C.A.; Hukriede, N.A.; Handin, R.I.; Davidson, A.J. Identification of adult nephron progenitors capable of kidney regeneration in zerbrafish. Nature. 2011, 470, 95-100.

[11] Ronco, C.; Davenport, A.; Gura, V. A wearable artificial kidney: dream or reality?. Nature Clinical Practice. 2008, 4, 604-605.

[12] medGadget. http://www.medgadget.com/2012/11/an-implantable-artificial-kidney-interview-with-ucsfs-dr-shuvo-roy.html (accessed February 6, 2013).

[13] The Kidney Doctor. http://www.thekidneydoctor.org/2013/01/global-nephrology-dialysis-in-india.html (accessed February 6, 2013).