Emerging Medical Technologies: PDF

Summary

This document explores emerging medical technologies, highlighting the need for technology assessment in global health. It examines the development of advancements in medical technologies, their potential impact worldwide, and the challenges in integrating them into practical healthcare. The book also aims to analyze the difference in health needs and resource limitations across the globe.

Full Transcript

1
Emerging medical technologies:
high stakes science and the need
for technology assessment

In the past century, advances in medical technol-
ogy have yielded enormous improvements in human
health. For example, our scientific understanding of
the immune response and the resulting development
of vaccines has vastly reduced the incidence of many
infectious diseases. Smallpox has killed more people
throughout history than perhaps any other infectious
disease. Yet, in 1980, the World Health Organization
announced that smallpox had been eradicated world-
wide through a program of vaccination (Figure 1.1).
Despite these advances, many medical technologies are
available to only a small segment of the world’s popu-
lation that can afford them.
Today, emerging technologies have the potential to
transform the future of healthcare, offering the potential
to diagnose and prevent disease before it strikes, to treat
disease in a targeted manner, and to utilize cells and
genes for patient-specific therapies. For example, gene
therapy offers the promise to cure fatal genetic diseases
such as cystic fibrosis and to reprogram a patient’s
immune system to more effectively fight HIV/AIDS,
the leading cause of death in sub-Saharan Africa.
Sequencing the genome of M. tuberculosis has pointed
to new molecular targets for more effective drugs to
Figure 1.1. The development of the smallpox vaccine and the
treat tuberculosis. Small silicon chips containing every subsequent eradication of the disease is an example of a powerful
gene in the human genome may soon be used to detect medical technology. CDC/ World Health Organization; Stanley O.
cancer at the earliest and most curable stages and to Foster.
2 Biomedical Engineering for Global Health

individually tailor therapeutic agents for each patient. which can significantly impact world health. Through-
Tissue engineering holds the promise to create artificial out the book, we present and apply tools to system-
organs, overcoming problems with the limited supply atically evaluate these new medical technologies. The
of donor organs. Novel, biologically active materials book is organized to address four central questions.
may be used to coat blood vessels within the heart
to prevent heart attacks, one of the leading causes of
death in the United States. Four central questions addressed
(1) What are the major human health problems
worldwide and how do these differ throughout
Medical technology the world?
The use of novel technologies to develop new (2) Who pays to solve problems in healthcare and
drugs, biologics, or medical devices designed to how does this vary throughout the world?
diagnose, treat or prevent disease. (3) How can we use technology to solve world
Bioengineering health problems?
The application of engineering design to develop (4) How do new technologies move from the
new medical technologies. laboratory to the bedside?

Biotechnology
The use of living systems to make or improve new
(1) What are the major health
products, frequently targeted toward improving
problems worldwide?
human health.
Global mortality data show a significant gap in health
status between developed and developing countries.
What is needed to bring these new technologies from Leading causes of death in the developed world include
the research laboratory to your physician’s office in cancer, ischemic heart disease, and stroke. In the devel-
a safe and affordable way? As a society, how should oping world, infectious diseases like tuberculosis and
we invest our limited financial and human resources to malaria are far more prevalent owing to widespread
develop new medical technologies? Can new technolo- poverty, poor infrastructure, and a lack of healthcare
gies reduce global disparities in health or will they sim- resources. A child born today in one of the least devel-
ply widen the gap in health status between developing oped countries is more than 1000 times more likely
and developed countries? In this textbook, we examine to die of measles, an easily preventable and curable
how bioengineers integrate advances in the physical, disease, than one born in an industrialized country.
information and life sciences to develop new medical Worldwide, more than 31 million adults and 2.0 million
technologies. To be effective, new healthcare technolo- children are living with HIV/AIDS, most in developing
gies must provide a better means of preventing, detect- countries. Over the next decade, noncommunicable dis-
ing or treating disease. At the same time, technologies eases such as diabetes and heart disease are expected to
must also be affordable to those who need them. The overtake infectious diseases and malnutrition as lead-
goal of bioengineering is to harness science to solve ing causes of death in developing countries. The frac-
health problems in the face of such constraints. Our tion of the global burden of disease linked to lifestyle
study of bioengineering for world health is organized to and behavior choices, currently 20–25%, is expected to
first understand both global health needs and resource increase throughout the world – for example, by 2020
limitations – as we will see, the healthcare problems and tobacco is expected to kill more people than any single
economic constraints vary dramatically throughout the disease, even HIV/AIDS. Understanding how health
world. With this beginning, we profile new technolo- needs differ throughout the world and how these needs
gies emerging from biotechnology and bioengineering are projected to change in the coming years is the first
 Emerging medical technologies 3

Table 1.1. Average health care expenditures per capita of selected
UN Millenium Development Goals WHO nations.
Some 80% of the world’s population live in
Country Avg. Health Care Expenditure per
developing countries. In 2000, 189 countries capita, 2001 (US$)
committed to a broad set of goals to meet the needs
Liberia $1
of the world’s poorest citizens. The goals include
India $24
the following.
China $49
Eradicate extreme poverty and hunger
! Halve the proportion of people whose income is
Colombia $105
Mexico $370
less than one dollar a day by 2015.
! Halve the proportion of people who suffer from Portugal $982

hunger by 2015. Israel $1641
Switzerland $3779

! Eliminate gender disparity in primary and
Achieve universal primary education
United States $4887

secondary education in all levels of education by
2015. step to enable the development of new technologies to
address these needs.
! Reduce the under-five mortality rate by two thirds
Reduce child mortality

by 2015. (2) Who pays to solve problems
in healthcare?
! Reduce the maternal mortality ratio by 75% by
Improve maternal health
Despite recent advances, many medical technologies are
available only to a small segment of the world’s pop-
2015.
ulation. As a result, standards of medical care differ

! Halt and begin to reverse the spread of HIV/AIDS
Combat HIV/AIDS, malaria and other diseases radically between the developed and developing world.
Average annual healthcare expenditures in high income
by 2015.
! Halt and begin to reverse the incidence of malaria
countries are more than $1800 per person, compared
to only $16 per person in the world’s least developed
and other major diseases by 2015. countries (Table 1.1). Even in high income countries,
the cost of new medical technologies is of great con-
! Halve the proportion of people without
Ensure environmental sustainability
cern. Over the past two decades, healthcare spending
has risen dramatically in the United States and through-
sustainable access to safe drinking water and
out the industrialized world, and this rise is expected to
sanitation by 2015.
continue through the next decade. In the USA, health-
Develop a global partnership for development care costs now account for one seventh of the nation’s
expenditures. The increasing use of new, expensive
The Millenium Country Profiles technologies, an aging population, and increased admin-
(http://unstats.un.org/unsd/mi/mi.asp) provide a istrative costs all contribute to the overall rise in health-
source of data to compare economic and health care spending. As we will see later, increasing health
status of countries and to monitor progress toward expenditures does not always improve health status. As
these goals. health spending grows beyond a minimum value, there
is a decreasing rate of return on investment, with fewer
years of life gained per dollar invested. In order to
achieve the promise of new technologies worldwide,
4 Biomedical Engineering for Global Health

Major areas of bioengineering
Tissue engineering and regenerative medicine
The use of engineering design principles to regenerate natural tissues and create new tissues using biological
cells and three dimensional scaffolds of biomaterials.

Molecular and cellular engineering
Engineering approaches to modify properties of molecules and cells to solve biotechnological and medical
problems.

Computational bioengineering
Use of computational tools to analyze large biological data sets such as in genomics or proteomics;
computational models to predict structure and behavior of large biological molecules and to guide design of
new drugs.

Biomedical imaging
Design of imaging systems (e.g. ultrasound), image analysis tools, and contrast agents to record anatomic
structure or physiologic function.

Biomaterials
The engineering design of materials compatible with biological organisms that can be used to make implants,
prostheses, and surgical instruments that do not provoke immune rejection.

Drug delivery
Design of materials and systems to achieve controlled release of drugs in physiologic systems.

Biomechanics
The study of mechanical forces in living systems and the use of engineering design to create prosthetic devices
and tools for rehabilitation.

Biosensors
Engineering design of systems to identify and quantify biological substances. Advances in microelectronics
have aided in developing miniature, implantable biosensors.

Biosystems engineering
Modeling complex, interacting networks of biological systems within cells and organisms to understand
physiology and disease and suggest therapeutic strategies to modify behavior.

our society must develop and evaluate technologies in resonance imaging, radiation therapy, and vaccines are
a cost-conscious manner. all examples of health-related technologies that have
become widespread within the past century. The heart–
(3) How can bioengineering solve global lung bypass machine, pacemakers and other technolo-
health problems? gies have revolutionized the treatment of heart disease,
Technology development begins with scientific knowl- reducing cardiovascular mortality by half over the past
edge; in health issues this often means an understand- 50 years. In this book, we will consider how new tech-
ing of a disease and its effects on the body. Bioengi- nologies can be used to diagnose, treat, and ultimately
neers build on this scientific knowledge to create new prevent the three leading causes of death throughout
technologies that solve healthcare problems. Magnetic the world: infectious disease, cancer, and heart disease.
 Emerging medical technologies 5

As we will see later, the development of new healthcare Answers to these four questions are complex and
technologies must take into account the societal and interrelated. We begin our journey to understand how
economic context in which they will be used and their bioengineering can be used to improve world health
potential status as a priority or a luxury at a given time. by examining a case study of the development of a
For example, development of a totally implantable artifi- new technology – the use of high dose chemotherapy
cial heart may provide a solution to the problem of end- and bone marrow transplant to treat advanced breast
stage heart failure in developed countries, but owing cancer. This case study illustrates the difficult personal
to differences in infrastructure and resources is unlikely and social issues that can arise as new technologies are
to be a practical solution in many developing coun- developed and tested, and will introduce many of the
tries. To help illustrate these challenges, throughout this issues that we will examine in more detail throughout
book, we will profile the experiences of several under- the text. We conclude our case study with a look at how
graduate students who carried out internships in sub- the process of healthcare technology assessment can be
Saharan Africa as a part of a course in Bioengineering systematically used to address these complex and sen-
and World Health. Their experiences highlight both the sitive issues in a scientifically sound manner.
opportunities and challenges of developing new tech-
nologies to improve world health.
Case study: breast cancer and bone
marrow transplant
(4) How do new technologies move from the
Breast cancer is both a devastating and a common dis-
laboratory bench to the patient’s bedside?
ease. If you are female and live in the United States,
New medical technologies developed in research labo-
you have a one-in-eight (12.5%) chance of develop-
ratories must be subjected to a rigorous testing proce-
ing breast cancer sometime in your life. When
dure to ensure that they are both safe and effective. In
detected early, there are many effective treatments for
many cases, this involves carrying out experiments with
breast cancer. However, few effective treatments exist
human subjects. How can we ensure that these exper-
for the disease in its later stages. Less than 20% of
iments are carried out in an ethical way? How can we
women are alive five years after the detection of Stage
balance the desire to bring promising new treatments
IV metastatic breast cancer, the most advanced form
to patients who need them as soon as possible against
of the disease. In the 1980s a promising new therapy
the risk of harming patients by allowing them access
was developed for women with metastatic breast can-
to therapies that haven’t been sufficiently tested? As
cer: high dose chemotherapy followed by bone marrow
healthcare consumers we are often faced with conflict-
transplant (HDCT+BMT).
ing media reports of the safety of new medical technolo-
Small, early clinical trials of this technique were very
gies. In order to make choices about our own healthcare,
promising. The effectiveness of a new cancer treat-
it is necessary to understand how medical research is
ment is initially measured by the fraction of patients
funded and how new drugs and medical devices are
who experience a complete or total response follow-
regulated.
ing treatment. In the 1980s, a number of small stud-
ies showed a substantial increase in the number of
Learn more about breast cancer patients with metastatic breast cancer who responded
Breast Cancer Facts and Figures 2005–2006. to this new therapy compared to historical experi-
(Atlanta, GA: American Cancer Society, Inc.; 2005). ence for patients treated with standard chemother-
apy. Although these results were exciting, they were
http://www.cancer.org/downloads/STT/ viewed with caution until the patients could be fol-
CAFF2005BrF.pdf lowed for a longer period of time. Many patients who
initially respond to therapy may relapse; thus long term
6 Biomedical Engineering for Global Health

Beyond Traditional Borders: Reports from
Student Interns
Kim Bennett accompanied Dr. Ellie Click across
Malawi conducting intensive training at hospitals as
part of a pilot project for the use of bloodspot PCR for
infant HIV diagnosis.
Dave Dallas and Tessa Elliott assisted in the
design and implementation of World Food Program
food distribution system at a pediatric AIDS clinic in
Mbabane.
Lindsay Zwiener and Rachel Solnick pilot-tested
software that generates pictorial medication guides,
which were developed as their Bioengineering &
World Health course projects. They assessed whether
these guides help caregivers in Botswana in the
proper dosing and timing of anti-retroviral (ARV)
medications, promoting adherence to ARV therapy.
Christina Lagos and Sophie Kim rolled out their
Bioengineering & World Health course project in the
SOS Village in Maseru. The project was an
after-school activities club to promote interest in
science and health education with a focus on
HIV/AIDS. They also implemented a Reach Out and
Read program at a pediatric AIDS clinic.
The course in Bioengineering & World Health was
developed and offered at The University of Texas at
Austin and at Rice University. Through a new
initiative called Beyond Traditional Borders, made
possible by a grant to Rice University from
the Howard Hughes Medical Institute through the
Undergraduate Science Education Program, students
at Rice University can travel to Africa for a summer
and implement the projects they developed as part of
this course. The inaugural class of interns kept a blog
describing their experiences. Throughout the book,
we include excerpts from the blog to provide a
student’s view of how bioengineering can improve
world health.

You can find more student blogs at:
www.owlsbeyondborders.rice.edu
 Emerging medical technologies 7

Departure: June 8th, 2007
Christina Lesotho
Coming from a close family, I have been doing a lot of explaining about my goals and purpose for this trip
and doing my best to calm the fears of my family. I know that they simply want me to be safe and are con-
cerned about me while I am gone, and I am used to the ways of overprotective Greek relatives. In the end,
I think I have convinced them that this will be the experience of a lifetime and that I have been looking forward
to something like this since I began college.
I was getting ready to record something in my personal journal last night and found that the last sentence I wrote the last
time I made an entry had to do with Africa. From my last weeks in Washington, D.C., working on health policy in Africa, I
expressed a desire to go and experience the challenges and situations first hand. “I want to go to Africa... why not me?”, that is
what I had written as I wondered why it always seemed so far-fetched or impossible that I would one day be able to visit. And
now it’s quickly approaching, and I feel so fortunate and excited for this opportunity.
I am prepared for some of the best and worst emotions I have ever experienced and
am ready to fully immerse myself in the work I am about to do in Lesotho. I feel almost
guilty for having somehow cheated during this pre-departure period... I have been
looking at tons of Google images of Maseru, Lesotho, and the surrounding area, and I
feel like I have some sort of unfair advantage as I travel. When I was younger and did not
use or have access to the Internet as much, traveling to a new place was always so
much more of a mystery and I always envisioned my destination so differently than it
turned out to be. I know that a bunch of Google images and travel sites will not do
Lesotho justice, but I still feel like I have done away with at least a bit of the mystery of
travel. Maybe I won’t do that next time.
I am looking forward to spending the next few days in Johannesburg with a
family-friend who grew up there. I will be there until the 12th when I will be meeting up
with Sophie at the airport to head to Maseru.
It will be nice to leave the hot and humid start of summer here in Florida and find the
cold beginnings of winter in southern Africa!

survival rates are often used as a better metric to deter- was little clinical evidence to show that it was superior
mine the effectiveness of a new cancer therapy. The to standard therapy. The story of what happened
three year survival rate measures the number of patients as this technology was developed and tested illustrates
still alive three years after beginning cancer therapy. In how political pressures can overwhelm science, leading
the early 1990s, a small study indicated that women to substantially increased medical costs and dramati-
with high risk breast cancer treated with HDCT+BMT cally reduced quality of life for patients.
had a 72% three year survival rate, dramatically
higher than the historical experience for women treated Breast cancer in the USA
with standard dose chemotherapy, which was only After skin cancer, breast cancer is the most common
38–52%. cancer among women, and accounts for almost one of
These studies offered new hope to women who faced every three cancers diagnosed in women in the United
high risk or metastatic breast cancer. HDCT+BMT is States. In 2005, more than 40,000 American women
a grueling treatment that has been described by Dr. are expected to die of breast cancer; only lung cancer
Jerome Groopman as “an experience beyond our ordi- causes more cancer deaths in women. An estimated
nary imaginings – the ordeal of chemotherapy taken to 211,240 new cases of breast cancer occurred in the
a near-lethal extreme.” In desperation, more than USA in 2005, and there are over 2.3 million women
41 000 American women with advanced breast cancer living in the USA who have been diagnosed with breast
endured HDCT+BMT in the 1990s, even though there cancer.
8 Biomedical Engineering for Global Health

Figure 1.2. Female breast cancer incidence rates by race and ethnicity in the United States as reported by SEER.
The rates are age adjusted to the 2000 USA standard population.

Figure 1.3. Female breast cancer death rates by race and ethnicity in the United States as reported by SEER.
The rates are adjusted to the 2000 USA standard population.
 Emerging medical technologies 9

Female breast cancer incidence rates have risen in
the USA from 1973 to 1998, as reported by the NCI
Surveillance, Epidemiology and End Results (SEER) Pro-
gram (Figure 1.2). Incidence rates have increased owing
Tonsil
to a combination of changes in reproductive patterns
(delayed childbearing, having fewer children) and bet-
ter early detection with mammography. Female breast Thymus Gland
cancer death rates in the USA during the same period
have decreased (Figure 1.3), primarily owing to bet-
ter early detection of more treatable cancers and to
improvements in breast cancer treatments.
Figure 1.4 shows an illustration of the female breast. Spleen
After childbirth, milk is produced in glandular tissue in
the breast, leading to milk ducts. This glandular tis-
sue is where most breast cancers develop. When cancer Lymph Nodes
cells are confined to these ducts, and have not spread
to surrounding fatty tissue, the disease is called Stage 0,
and is completely curable with surgical excision. Lesions
which have spread to the surrounding fatty tissue but Lymphatic Vessels

Chest wall

Pectoralis muscles

Lobules

Nipple Figure 1.5. Lymphatic system. Source: SEER Training Modules,
surface Lymphoma. US National Cancer Institute. 2009.
http://training.seer.cancer.gov/
Areola
duct
are less than 2 cm in diameter are referred to as Stage I
lesions, and also have excellent prognosis, with a 100%
five year survival rate. A series of lymphatic vessels,
leading to lymph nodes under the armpit (axillary lymph
Fatty tissue nodes), drain breast tissue (Figure 1.5). Breast can-
cer cells can migrate from the initial lesion and enter
Skin these lymphatic vessels, providing a way for breast can-
cer cells to spread to other distant organ sites (metasta-
Figure 1.4. The human female breast. Source: SEER Training size). If the cancer has spread to one–three lymph nodes
Modules, Breast Cancer. US National Cancer Institute. 2009. close to the breast but not to distant sites, it is referred
http://training.seer.cancer.gov/ to as a Stage II lesion, and the five year survival rate is in
10 Biomedical Engineering for Global Health

Table 1.2. Breast cancer staging. cells cannot repair damage caused by chemotherapy
Stage Definition 5 yr drugs so they die.
survival Rapidly dividing normal cells may also be affected
Stage 0 Cancer cells are located within a duct 100% by chemotherapy drugs, but they can repair this dam-
and have not invaded the surrounding age. Because chemotherapy drugs affect rapidly dividing
fatty breast tissue
normal cells, they give rise to many undesirable side
Stage I The tumor is 2 cm or less in diameter 100%
effects. The cells which line the gastrointestinal tract
and has not spread to lymph nodes or
distant sites. divide rapidly; thus chemotherapy can lead to nausea,
Stage II The cancer has spread to 1–3 lymph 81–92% vomiting, mouth sores and loss of appetite. Cells in the
nodes close to the breast but not to hair follicles divide rapidly and chemotherapy can lead
distant sites to hair loss. Rapidly dividing cells in the bone mar-
Stage III The cancer has spread to 4–9 lymph 54–67% row which produce oxygen carrying red blood cells,
(High risk) nodes close to the breast but not to
infection fighting white blood cells, and platelets impor-
distant sites
tant in blood clotting are also affected by chemotherapy
Stage IV Cancer has spread to distant organs 20%
(Metastatic) such as bone, liver or lung or to lymph drugs. Chemotherapy patients are thus at high risk for
nodes far from the breast. infection, bleeding and fatigue. While these side effects
Reprinted by permission of the American Cancer Society, Inc. from are temporary, chemotherapy can also produce perma-
www.cancer.org. All rights reserved. nent side effects such as premature menopause and
infertility.
the range 81–92%. Stage III breast cancers involve more
than four nodes, and because the five year survival rates
High dose chemotherapy
are so low (54–67%) are referred to as “high-risk breast
Because chemotherapy can damage both cancer cells
cancers.” In metastatic breast cancer (Stage IV), the dis-
and rapidly dividing, but crucial, normal cells, can-
ease has spread from the lymphatics to other organ sites
cer treatment must strike a balance between com-
far from the breast, such as the brain. The five year sur-
pletely destroying all cancer cells while causing
vival rate for metastatic breast cancer is only 20%. The
minimal damage to normal cells. In the 1980s a
stages of breast cancer and the prognosis for each stage
number of dose comparison studies of chemotherapy
are summarized in Table 1.2.
to treat metastatic breast cancer showed that a higher
dosage of chemotherapy was associated with a higher
Treatments for breast cancer response rate. Scientists and clinicians hypothesized
There are many treatments for breast cancer. Treatment that metastatic breast cancer could be treated more
for most early cancers involves some form of surgery effectively with higher doses of chemotherapy. Unfor-
to remove the cancer cells. If the lesion is small, only tunately, such high doses completely destroy the bone
a portion of tissue may be removed (lumpectomy), marrow, leaving patients with no way to continue to
or the entire breast may be removed (mastectomy). produce the cells of the blood system and the immune
Larger tumors may be treated using chemotherapy. system, which are necessary for life.
In some cases, chemotherapy may be used to shrink Our blood consists of four components: plasma, red
larger tumors so that they can be removed surgically; in blood cells, white blood cells, and platelets. Plasma
others it may be used following surgery to reduce risk of carries nutrients and hormones throughout the body.
recurrence. In chemotherapy, drugs which are toxic to Red blood cells deliver oxygen throughout the body,
cancer cells are given intravenously or by mouth. These while white blood cells are necessary to fight infec-
drugs travel through the bloodstream, reaching cancer tions. Platelets are necessary for blood clotting following
cells throughout the body. Chemotherapeutic drugs injury. Throughout our lives, our blood cells are con-
interfere with ability of cells to divide; many cancer tinually renewed within the bone marrow. The source
 Emerging medical technologies 11

Figure 1.6. Red and white blood cells are
derived from cells of the bone marrow.

of all these cells is the pluripotent hematopoeitic stem (PBSCs) which are found in the blood. In a transplant,
cell which can give rise to all the types of blood cells these stem cells are isolated from the blood in a pro-
(Figure 1.6). Laboratory experiments in mice show that cess known as apheresis. The patient is given medica-
a single stem cell can yield the half-trillion blood cells tion to increase the number of stem cells in the blood-
of an entire mouse. Clinicians theorized that if the stream. Next, blood is removed from the body through
bone marrow was completely destroyed in high dose a central venous catheter and passes through a machine
chemotherapy, a bone marrow transplant could be done that removes the stem cells (Figure 1.7). The blood is
to restore these hematopoeitic stem cells; in fact such then returned to the patient and the collected stem cells
bone marrow transplants had proven very successful in are stored for future transplantation. The entire process
the treatment of cancers of the bone marrow. takes 10–12 hours, and yields enough stem cells to fill
one syringe.
The initial attempts to transplant bone marrow took
Learn more about bone marrow place in Cooperstown, NY during the 1950s. The
transplants effects of the atom bomb used at the end of World War
In his article, “Bone marrow transplant: a healing II sparked a tremendous interest in identifying ways
hell,” Dr. Jerome Groopman describes the to restore bone marrow. One reason that the bomb’s
experience of two patients who undergo bone radiation was so deadly was because it destroyed the
marrow transplants. bone marrow cells of its victims, leading to hemor-
J. Groopman. Bone marrow transplant: a healing rhage (uncontrolled bleeding) and the inability to fight
hell. The New Yorker (19 October 1998), pp. 34–39. off infection. At the time physicians could successfully
transfuse oxygen carrying red blood cells from compat-
ible donor to needy recipient.
Bone marrow transplants However, bone marrow cells could not be transfused.
Stem cells are found in high concentration in the bone Invariably, the recipient’s body identified them as for-
marrow, and can be harvested for transplantation in a eign invaders and destroyed them.
painful procedure. More recently, stem cells transplants One researcher who was especially interested in the
have been carried out using peripheral blood stem cells bone marrow transplant problem was Don Thomas.
12 Biomedical Engineering for Global Health

Apheresis technology
Most stem cells are found in the bone marrow, but some, called peripheral blood stem cells, can be found
in the blood. It is typically much more difficult to harvest bone marrow than cells in peripheral blood –
harvesting bone marrow requires hospitalization and general anesthesia. Typically, the concentration of stem
cells in the peripheral blood is very low, so patients are given growth factors to increase the concentration of
peripheral blood stem cells for several days prior to harvesting stem cells.
During apheresis, blood is removed from a large vein in the arm and sent to a machine which contains a
centrifuge to separate white blood cells. Anticoagulants must be added to the blood to prevent it from clotting.
The centrifuge spins the entering blood, and the resulting centrifugal force separates the various components
of blood – plasma, red blood cells and white blood cells – based on differences in their density. The red blood
cells are pushed to the outside of the centrifuge, while plasma remains near the center of the rotor. A layer of
white blood cells called buffy coat separates the plasma and red blood cells. This layer contains the peripheral
blood stem cells and is separated. The remaining blood is returned through a tube to the patient’s other arm.
A successful transplant requires collection of a large number of peripheral blood stem cells – approximately
five million stem cells per kilogram of body weight are required. Thus, we must quantify the number of
peripheral blood stem cells harvested during apheresis to determine whether a sufficient number have been
collected. When viewed through a standard microscope the stem cells can’t be differentiated from other white
blood cells. However, stem cells express a protein called CD34 on their membrane. The fraction of CD34
positive cells can be quantified by labeling the cells with a fluorescent dye linked to a molecule that binds to
CD34 and using a special machine called a flow cytometer to count the number of CD34 positive cells. Over
20 liters of blood must be processed (the entire blood volume must be treated four times) to collect sufficient
cells for later transplant, and apheresis is typically performed over several days. These cells are then treated
with cryopreservatives and frozen to be injected into the patient following the high dose chemotherapy
procedure [13, 14].

Thomas treated patients with cancer of the bone mar- eign invaders and the patient’s own cells. The histo-
row (leukemia) with chemotherapy. He believed that compatibility markers explained the failure of previous
providing new, healthy bone marrow cells was essential transplant attempts and held the key to future success.
to curing leukemia. He tested various transplant tech- When not properly matched, the patient’s immune sys-
niques in dogs initially, and then in patients with late tem would reject transplanted cells. Proper matching of
stage leukemia. In early trials, every patient who under- histocompatibility markers between donor and recipi-
went transplantation died. “Things were pretty grim”, ent led to successful results in dogs. With this advance,
Thomas later remarked. After four years of unsuc- Thomas resumed human trials, which led to successful
cessful transplantations attempts, he stopped human treatment for leukemia. Thomas (Figure 1.8) received
trials. the Nobel Prize in 1990 for his important work in this
Eight years later, Thomas identified protein mark- area.
ers on the surface of white blood cells. These his- Today bone marrow transplantation is a successful
tocompatibility markers are unique to each individual treatment for leukemia. In the past 40 years the five
and are found on the surface of nearly every cell in the year survival rate for leukemia has more than tripled,
body, but are particularly numerous on the surface of from 14% in 1960–63 to 49% in 1995–2002. How-
white blood cells. Histocompatibility markers enable a ever, it is still a gruelingly difficult treatment. Dr. Jerome
patient’s immune system to differentiate between for- Groopman describes the experiences of two patients
 Emerging medical technologies 13

diagnosed with leukemia. She received a bone marrow
transplant, and recounts her experience in Groopman’s
article. “It was a complete nightmare. For days, I’d be
on all fours and just retch and retch. I looked like a
lobster, and thought I had bugs crawling on me. I’d hit
myself and scream. I was in that sterile bubble, and for-
got what skin against skin felt like. That was lost. I just
wanted to hold on to my mom or dad, like a two-year-
old, and I couldn’t. I had terrible diarrhea, a blistering
rash all over my body, and jaundice. I was the color of
an egg yolk.”

A new technology for advanced breast cancer,
HDCT+BMT
With the success of bone marrow transplant for
leukemia, clinicians hypothesized that extremely high
dose chemotherapy could be used to treat metastatic
breast cancer if followed by a bone marrow transplant.
In this case, the patient’s own stem cells could be har-
vested prior to the chemotherapy and then reinfused
Figure 1.7. An apheresis machine. Copyright Caridian BCT, Inc. following treatment, thus insuring a perfect histocom-
2009. Used with permission. patibility match. Compared to standard chemotherapy,
this procedure was initially very expensive (>$140,000)
who received bone marrow transplants in his article, and initial trials had very high treatment associated mor-
“Bone marrow transplant: a healing hell.” Courtney tality (death) rates, in the range 7–22% [16, 17]. Despite
Stevens was a high school sophomore when she was the extreme expense and side effects, the combination

Figure 1.8. Don Thomas and his wife and
partner in research, Dottie, with childhood
leukemia survivors. Used with permission
from ⃝
c Jim Linna.
14 Biomedical Engineering for Global Health

of HDCT+BMT offered some of the only promise for the there was a strong public demand for HDCT+BMT, even
treatment of metastatic breast cancer. An early study in the absence of good clinical evidence to indicate that it
showed that the three year survival rates of women with worked.
high risk breast cancer treated with HDCT+BMT were
40% higher than those of women who had not partici- Public reaction to new hope
pated in the trial and had received standard chemother- In 1991, the television show 60 Minutes aired a piece
apy. While this study offered hope for the new treat- decrying the company Aetna’s decision to deny insur-
ment, it was criticized for several reasons. It was a small ance coverage for HDCT+BMT to treat breast cancer
study, involving only 85 patients, and did not randomly. At the same time, Nelene Fox, a 38 year old mother
assign women to receive either the new therapy or the of three who was diagnosed with advanced breast can-
standard therapy. It also only included women whose cer, sued her insurance company. The company,
disease initially responded to standard chemotherapy HealthNet, refused to pay for HDCT+BMT for Fox, even
and who therefore might be expected to do better than though it had recently paid for a relative of its CEO to
those whose disease was not responsive to standard receive the same treatment. Mrs. Fox and her family
treatment. sued HealthNet for failure to provide coverage. In the
meantime the family raised more than $210 000 so she
could receive HDCT+BMT. Mrs. Fox died of breast can-
Learn more about HDCT+BMT
cer before a verdict was reached; her family argued that
Drs. Michelle Mello and Troyen Brennan provide a
the delay in receiving the treatment contributed to her
more complete account of the early controversy
death. The family was awarded $89M, then the largest
surrounding the use of HDCT+BMT to treat breast
jury verdict ever against an HMO. The case received
cancer.
widespread publicity, and in 1993 the Massachusetts
M. M. Mello and T. A. Brennan. The controversy
legislature mandated that insurers provide coverage for
over high-dose chemotherapy with autologous bone
HDCT+BMT for advanced breast cancer. In 1994, insur-
marrow transplant for breast cancer. Health Affairs,
ers approved coverage for 77% of breast cancer patient
20:5 (2001), 101–17.
requests for HDCT+BMT as part of clinical trial par-
ticipation. However, approval was highly arbitrary,
In order to gain more evidence, several larger clini- even for similar patients covered by the same insurer.
cal trials were initiated in which women with advanced Nine of 12 large insurers surveyed indicated that the
breast cancer were to be randomly selected to receive threat of litigation was a major factor in their decision
either standard chemotherapy or HDCT+BMT. Clini- to provide coverage.
cians planned to compare the percentage of patients In 1995, the results of a small, short randomized
who were still alive (survival rates) three and five years trial of 90 patients in South Africa was reported by
following therapy in both arms of the trial as well as the the lead physician, Dr. Werner Bezwoda. Dr. Bez-
percentage of patients whose cancer had not recurred woda’s study showed that, on average, women who
(disease-free survival rates). received HDCT+BMT for metastatic breast cancer sur-
Such randomized clinical trials are considered to be vived twice as long without a relapse than women
the most important kind of clinical evidence to indicate who received standard chemotherapy. By this time,
whether a new therapy is better, the same, or worse more than 80% of American physicians believed that
than a standard therapy. Typically, in the absence of women with metastatic breast cancer should be treated
such evidence, a therapy is considered to be experi- with HDCT+BMT, and these results seemingly sup-
mental and most insurance companies in the USA will ported that conclusion. During the 1990s, more
not pay for it. Because there are so few effective treat- than 41,000 patients underwent HDCT+BMT for breast
ments available for advanced breast cancer however, cancer despite a paucity of clinical evidence regarding
 Emerging medical technologies 15

Breast cancer in developing Learn more about insurance coverage for
countries HDCT+BMT
More than 1.2 million people worldwide were The Aetna insurance company will only pay for
diagnosed with breast cancer in 2005. Women in HDCT+BMT as part of a controlled clinical trial
developed countries have access to imaging sponsored by the Food and Drug Administration or
technologies such as mammography and ultrasound the National Cancer Institute. This article explains
to aid in early detection and to advances in their rationale.
hormonal treatments and chemotherapy. However, Breast cancer: high dose chemotherapy with
women in developing countries frequently do not autologous sterm cell support. Clinical Policy
have access to these lifesaving technologies. Bulletins (Aetna Inc, 7 October 2005).
Maria Saloniki is a 60 year old mother of ten http://www.aetna.com/cpb/data/CPBA0507.html.
living in the United Republic of Tanzania. This
image of her (below) is used courtesy of WHO/
Chris de Bode. When she was 57 she experienced effectiveness. In fact, it was so difficult to recruit
fever, a swollen armpit and pain. Over three years, patients to randomized phase III clinical trials (because
she visited local healers, various clinic doctors, and women were afraid they would be randomly selected to
even traveled to Nairobi, Kenya to seek treatment. receive the standard therapy) that the trials took more
She was prescribed herbal ointments, antibiotics, than twice as long to complete than planned.
and told that nothing could be done for her In 1999, at the meeting of the American Society of
condition. Finally, three years after her initial Clinical Oncology, the results of five randomized clinical
symptoms she traveled to Dar es Salaam, where a trials were reported. Sadly and surprisingly, four of the
biopsy showed that she had breast cancer and she studies showed no survival benefit with HDCT+BMT;
began chemotherapy. some showed it took a little longer for cancer to return.
Her husband has had to borrow a large sum to Figures 1.9a and 1.9b compare the survival and dis-
finance her care, and can’t afford both the cost of ease free survival rates over time in women receiving
the treatment and bus fare to come and visit her either HDCT+BMT or standard therapy in one of the tri-. als; no meaningful differences were noted in either case.
Only one South African study, again from Dr. Bezwoda,
showed a survival benefit. In his study, women
with high-risk breast cancer had an 83% chance of five
year survival if they received HDCT+BMT, compared
to only a 65% chance of five year survival with stan-
dard chemotherapy. The average disease free survival
time was 100 months for women receiving HDCT+BMT,
versus only 47.5 months average disease free survival
for those receiving standard chemotherapy. The poor
results of the four negative HDCT+BMT trials were
widely reported in the media.
Public reaction was again strong. Prior to the neg-
ative trial results, in 1996–98, Anthem Insurance saw
the number of women requesting HDCT+BMT for
breast cancer increase. In 1999, prior to the trial
results, the company expanded indications for which
16 Biomedical Engineering for Global Health

(a) Scientific misconduct
Scientists could not understand why one trial showed
improved survival with HDCT+BMT, while four other
trials showed no benefit. A team of scientists was sent to
audit the results of the South African trial (Figure 1.10).
Unfortunately, the audit team could not find records for
many of the patients supposedly enrolled in the study.
They found that the study showed little evidence of
randomization, and that many patients whose records
could be found did not meet the eligibility criteria for the
(b) trial. They also found that the trial had not been
properly approved by the Institutional Review Board at
Dr. Bezwoda’s university, which is required to approve
all research involving human subjects in advance. The
university conducted a formal ethics inquiry, and Dr.
Bezwoda admitted to a “serious breach of scientific
honesty and integrity.” The university fired Dr.
Bezwoda, and many of his publications were formally
retracted from the journal in which they had been
published.
Figure 1.9. Disease free survival (a) and survival (b) rates over time
in women receiving either HDCT+BMT or standard therapy from a Where are we now?
randomized clinical trial. Copyright ⃝
c 2003 Massachusetts Scientists continued to follow the patients enrolled in
Medical Society. All rights reserved. the five randomized clinical trials originally reported
in 1999 (Table 1.3). Even with longer follow up, it
appears that there is no survival benefit to HDCT+BMT
Learn more about public reaction
at either three years or five years following treatment as
Denise Grady covered the announcement of these
compared to standard chemotherapy. There is a small
results for the New York Times.
but significant increase in disease free survival at three
D. Grady. Doubts raised on a breast cancer
years with HDCT+BMT, but this advantage disappears
procedure. New York Times (16 April 1999).
at five years. Serious side effects are more common with
Joanne Silberner covered the announcement of
HDCT+BMT compared to standard therapy, but most
these results for National Public Radio.
are reversible. Patients report that quality of life is lower
J. Silberner. Breast cancer. Radio program,
at six months following treatment with HDCT+BMT,
National Public Radio (16 April 1999).
but similar to that of standard chemotherapy one year
http://www.npr.org/templates/story/
following treatment. The costs of HDCT+BMT have
story.php?storyId=1049404.
been reduced to about $60,000, which is still nearly
two times that of standard chemotherapy.
they would approve HDCT+BMT. After the trial results Most physicians and insurance companies now agree
were reported in 1999, they received only four requests that HDCT+BMT should not be used to treat high risk
for such coverage, despite the expanded coverage. Most breast cancer outside of a randomized clinical trial.
insurance companies now cover HDCT+BMT for breast Research in this area continues, to identify if longer
cancer only as part of an FDA or NCI sponsored clinical follow up (7–10 years) will show advantages of high
trial. dose therapy, or to determine if there are sub-groups of
 Emerging medical technologies 17

Table 1.3. Results of five randomized clinical trials of HDCT+BMT for breast cancer [21, 28–30].

Study # Randomized % survival Disease free survival
patients
Stadtmauer 184 32% 3 year BMT 9.6 months BMT
Metastatic 38% 3 year control 9.0 months control
Lotz 61 29.8% 5 year BMT 9% disease free at 5 yrs BMT
Metastatic 18.5% 5 year control 9% disease free at 5 yrs control
Peters 783 79% 3 year BMT 71% disease free at 3 yrs BMT
High Risk 79% 3 year control 64% disease free at 3 yrs control
Rodenhuis 885 75% 5 year BMT 65% disease free at 5 yrs BMT
High Risk 73% 5 year control 59% disease free at 5 yrs control
p = 0.09∗
Tallman 511 58% 6 year BMT 49% disease free at 6 yrs BMT
High Risk 62% 6 year control 47% disease free at 6 yrs control

Figure 1.10. The results of Dr. Bezwoda’s
controversial trial.

women who benefit from high dose therapy (for exam- media, the courtroom or the laboratory? In an age
ple those whose tumors are negative for certain genetic where high-technology treatments are one of the most
markers or who have 10 or more axillary lymph nodes powerful drivers of healthcare costs, these are crucial
which show cancer cells). New technologies to com- questions.
pletely rid the transplanted stem cells of any rogue can-
cer cells may also reduce recurrence rates in women
Healthcare technology assessment
treated with HDCT+BMT. However, all of these theo-
Professors Frazier and Mosteller, experts in health pol-
ries must be subject to rigorous testing if they ever are
icy and management, have stated, “If we are to have
to become methods of standard treatment.
good medical care, we need to know what works, and
this cannot be known without systematic technology
Lessons learned assessment. The intuitions of physicians and the guesses
The example of HDCT+BMT to treat breast cancer of biologists are not adequate guides to the best treat-
illustrates the dangers of allowing political pressures ments.” How then do we assess new technologies
to overwhelm scientific evidence. What is the proper objectively, avoiding political pressures that can lead
forum to resolve such controversies? Should it be the us to waste precious healthcare resources and subject
18 Biomedical Engineering for Global Health

thousands of patients to punishing, but ineffective, Homework
treatments? 1. Advanced breast cancer has a high mortality. Initial
clinical trials indicated that high dose chemotherapy
followed by a bone marrow transplant could reduce
Healthcare technology assessment the mortality rate by as much as 40%.
The systematic process of evaluating the safety, a. Why did physicians and scientists believe that
short term and long term efficacy, acceptability and higher doses of chemotherapy would be more
cost effectiveness of a new medical technology. effective than standard therapy for advanced
breast cancer?
Answering these questions is increasingly important b. Why is it necessary to give patients a bone
in a world where early studies of new medical advances marrow transplant following high dose
can receive substantial publicity in the popular press chemotherapy? What will happen if they do not
before randomized clinical trials are completed. A recent receive a bone marrow transplant?
study published in the Journal of the American Medical c. In the context of this example, discuss how
Association compared conclusions presented in highly political pressures overwhelmed scientific
cited articles in major general clinical journals to those evidence. How could this be avoided in the
of subsequent studies with larger sample size or bet- future?
ter controlled design. Results showed that nearly 1/3 d. Find a news report describing a new health
of highly cited studies were later contradicted and that technology published in the last year. In your
this was most likely for nonrandomized studies. opinion, does this news report provide balanced
As we examine these important issues in this book, discussion of the potential promise and the
we will build a toolkit to help us answer politically potential limitations of this technology?
sensitive questions about how to use limited resources 2. The Pew Global Attitudes Project is a worldwide
in a deliberate and unbiased manner. Technology survey of public opinion. In 2002, more than 38,000
assessment will be an important part of our toolkit, and people in 44 countries were asked to assess the
it is the subject of Chapter 2. quality of their own lives, their level of optimism
about their lives in the next five years, and to rank
problems faced by themselves and their countries.
Bioengineering and Global Health Project In this exercise, you are asked to review the results
Project overview of this survey and to prepare several graphs
Design a new technology to solve a health problem, summarizing the results.
present a mock prototype of the new technology to Pew World Attitudes Website: http://people-press.
a design review committee, and design a clinical org/reports/display.php3?ReportID=165
trial to test the new technology. Pew World Attitudes Report:
Throughout this text, you will use the http://people-press.org/reports/pdf/165.pdf
engineering design method to design a new solution You will examine results in countries profiled in
to an important health problem. You will identify an Unit 2: the United States, Canada, China, India
important health problem, and carry out research to and Angola. For parts a–e, please construct
understand the scope of the problem and limitations graphs, for part f provide a discussion which
of current health technologies. You will follow the supports your findings.
engineering method to design a new solution which a. What fraction of people surveyed in each country
meets the constraints you identify. You will create a expressed satisfaction with their own lives?
physical prototype of your design and will present it b. What fraction of people surveyed in each country
to the class as part of a design review exercise. report that they are unable to afford food?
 Emerging medical technologies 19

c. What fraction of people in each country cite the (1992–2003) and SEER 9 Regs Public-Use, Nov 2005
following as a very big problem in their country? Sub (1973–2003), National Cancer Institute, DCCPS,
Poor drinking water Surveillance Research Program, Cancer Statistics
Branch, released April 2006, based on the November
Crime
2005 submission.
AIDS and disease Surveillance, Epidemiology, and End Results (SEER)
d. What fraction of people in each country believe Program (www.seer.cancer.gov) SEER∗ Stat Database:
that the following is the greatest danger facing Mortality – All COD, Public-Use With State, Total U.S.
the world today? for Expanded Races/Hispanics (1990–2003) and All
Nuclear weapons COD, Public-Use With State, Total U.S. (1969–2003),
National Cancer Institute, DCCPS, Surveillance
AIDS and other infectious diseases
Research Program, Cancer Statistics Branch, released
e. What fraction of people surveyed in each country
April 2006. Underlying mortality data provided by
are optimistic that their lives will improve in the NCHS (www.cdc.gov/nchs).
next five years? Silverthorn DU. Human Physiology: An Integrated
f. Compare general agreement on questions 4 and 5 Approach. 2nd edn. Upper Saddle River, NJ: Prentice
throughout countries in Africa and Europe. Hall; 2001.
American Cancer Society. Detailed Guide: Breast Cancer:
How is Breast Cancer Staged? Sep 18 2006 [cited 2007].
References Available from: http://www.cancer.org/docroot/CRI/
Health in the Millenium Development Goals: Millenium content/CRI 2 4 3X How is breast cancer staged
Development Goals, Targets and Indicators Related to 5.asp
Health. World Health Organization; 2004. Walker F, Roethke SK, Martin G. An overview of the
Glossary of Globalization, Trade and Health Terms: rationale, process, and nursing implications of
Health Transition. World Health Organization; 2007. peripheral blood stem cell transplantation. Cancer
Beaglehole R, Irwin A, Prentice T. The World Health Nursing. 1994 Oct 10; 17(2): 141–8.
Report 2004: Changing History. Geneva, Switzerland: Hansson M, Svensson A, Engervall P. Autologous
The World Health Organization; 2004. peripheral blood stem cells: collection and
Coulter SL, Cecil B. Assessing the Value of Health Care processing. Medical Oncology. 1996 Jun; 13(2): 71–9.
in Tennessee. Chattanooga: Blue Cross Blue Shield of Leukemia, Lymphoma, Myeloma, Facts and Statistics
Tennessee; 2003. 2006–2007. White Plains, NY: Leukemia and
Breast Cancer Facts and Figures 2005–2006. Atlanta, GA: Lymphoma Society; 2007.
American Cancer Society, Inc.; 2005. http://www. White K. Notebook: bone marrow transplant for breast
cancer.org/downloads/STT/CAFF2005BrF.pdf cancer is questioned on basis of incomplete data.
Peters WP, Ross M, Vredenburgh JJ, Meisenberg B, Journal of Women’s Health and Gender-Based Medicine.
Marks L, Winer E, et al. High-dose chemotherapy and 1999; 8(5): 577–82.
autologous bone marrow support as consolidation after Brockstein BE, Williams SF. High-dose chemotherapy
standard-dose adjuvant therapy for high-risk primary with autologous stem cell rescue for breast cancer:
breast cancer. Journal Of Clinical Oncology: Official yesterday, today, and tomorrow. Stem Cells. 1996; 14:
Journal Of The American Society Of Clinical Oncology. 79–89.
1993 June; 11(6): 1132–43. Abegunde D, Beaglehole R, Durivage S, Epping-Jordan
Groopman J. Bone marrow transplant: a healing hell. J, Mathers C, Shengelia B, et al. Preventing Chronic
The New Yorker. 1998 October 19: 34–9. Diseases: A Vital Investment. Geneva, Switzerland:
Mello MM, Brennan TA. The controversy over World Health Organization; 2005.
high-dose chemotherapy with autologous bone marrow Aetna. Breast cancer: high-dose chemotherapy with
transplant for breast cancer. Health Affairs (Project autologous stem cell support. Clinical Policy Bulletins
Hope). 2001 Sep–Oct; 20(5): 101–17. 2005 October 5 [available from:
Surveillance, Epidemiology, and End Results (SEER) http://www.aetna.com/cpb/data/CPBA0507.html].
Program (www.seer.cancer.gov) SEER∗ Stat Database: Bezwoda WR, Seymour L, Dansey RD. High-dose
Incidence – SEER 13 Regs Public-Use, Nov 2005 Sub chemotherapy with hematopoietic rescue as primary
20 Biomedical Engineering for Global Health

treatment for metastatic breast cancer: a randomized Horton R. After Bezwoda. Lancet. 2000 Mar 18;
trial. Journal Of Clinical Oncology: Official Journal Of 355(9208): 942–3.
The American Society Of Clinical Oncology. 1995 Oct; Rodenhuis S, Bontenbal M, Beex LV, Wagstaff J, Richel
13(10): 2483–9. DJ, Nooij MA, et al. High-dose chemotherapy with
Tallman MS, Gray R, Robert NJ, LeMaistre CF, Osborne hematopoietic stem-cell rescue for high-risk breast
CK, Vaughan WP, et al. Conventional adjuvant cancer. The New England Journal Of Medicine. 2003 Jul
chemotherapy with or without high-dose chemotherapy 3; 349(1): 7–16.
and autologous stem-cell transplantation in high-risk Stadtmauer EA, O’Neill A, Goldstein LJ, Crilley PA,
breast cancer. The New England Journal Of Medicine. Mangan KF, Ingle JN, et al. Conventional-dose
2003 Jul 3; 349(1): 17–26. chemotherapy compared with high-dose
Bezwoda WR. Randomised, controlled trial of high dose chemotherapy plus autologous hematopoietic stem-cell
chemotherapy versus standard dose chemotherapy for transplantation for metastatic breast cancer.
high risk, surgically treated, primary breast cancer. Philadelphia Bone Marrow Transplant Group. The New
Proceedings of the American Society of Clinical Oncology. England Journal of Medicine. 2000 Apr 13; 342(15):
1999; 18: 2a. 1069–76.
Grady D. Doubts raised on a breast cancer procedure. Antman KH. Randomized trials of high dose
New York Times. 1999 April 16; Sect. A1. chemotherapy for breast cancer. Biochimica Et
Silberner J. Morning Show: breast cancer. National Biophysica Acta. 2001 Mar 21; 1471(3): M89–98.
Public Radio. 1999 April 16. http://www.npr.org/ Frazier HS, Mosteller F. Medicine Worth Paying For:
templates/story/story.php?storyId=1049404. Assessing Medical Innovations. Cambridge, Mass.:
Anthem. Insurance payments for bone marrow Harvard University Press; 1995.
transplantation in metastatic breast cancer. The New Ioannidis JP. Contradicted and initially stronger effects
England Journal of Medicine. 2000 April 13; 342(15): in highly cited clinical research. JAMA: The Journal Of
1138–9. The American Medical Association. 2005 Jul 13; 294(2):
New audit uncovers scientific misconduct in 1995 South 218–28.
African study on metastatic breast cancer. American Face to Face with Chronic Desease: Maria’s Story:
Society of Clinical Oncology. 2001 April 26. Fighting Cancer. World Health Organization, 2005.
 2
Bioengineering and technology
assessment

In Chapter 1, we examined the development and intro- The case study of HDCT+BMT for advanced breast
duction of a new technology that initially appeared as cancer underscores the need for a systematic method
if it could provide new hope to women with advanced to guide the development and introduction of new tech-
breast cancer. Small clinical trials showed that women nologies. In Chapter 1, we saw how the interplay of des-
with high risk or metastatic breast cancer treated with perate patients seeking the best treatment, early media
high dose chemotherapy and bone marrow transplant publicity and a scientist who falsified data all combined
(HDCT+BMT) had substantially better response rates to slow the progress of medical science. In the end,
and survival compared to historical experience with many patients unnecessarily underwent an expensive
standard chemotherapy. These early promising results and highly toxic therapy. How can we prevent this from
were widely publicized, and even though the therapy happening with future technologies? In this chapter,
had serious side effects, it was used to treat thousands we will consider the methodology of technology assess-
of women. Usually, before a new technology is adopted, ment, which provides a systematic set of tools to deter-
randomized clinical trials are conducted to compare the mine the performance of a new technology and to assess
performance of the new technology to that of exist- the impact of using the technology both for individual
ing technologies. In such randomized clinical trials, patients and for society as a whole. When used properly,
patients are randomly selected to receive either the cur- technology assessment can help ensure that new med-
rent standard therapy or the new therapy; outcomes ical technologies are introduced on the basis of sound
such as response rate, survival and side effects are scientific evidence and not simply on the opinions of
then compared for the two groups of patients. However, physicians and scientists, or the hopes of patients.
because patient demand was so high for HDCT+BMT, As a prelude to technology assessment, we consider
randomized clinical trials took much longer to com- the steps involved in bringing a new technology from
plete than planned. Ultimately, randomized clinical tri- the laboratory bench to the patient’s bedside. Figure
als showed that HDCT+BMT did not improve survival 2.1 shows a roadmap of this process. Bioengineers build
for most patients. The promising results of early tri- on the scientific understanding of a disease to design
als were misleading due to a combination of factors, new healthcare technologies. New technologies must
including their small size, selection bias and scientific be rigorously tested to determine whether they are safe
misconduct. and effective. This testing process can include preclini-
22 Biomedical Engineering for Global Health

(b)
(c)
(a)

(d)

(e)

(f)

(g)

Figure 2.1. A roadmap of the healthcare technology development process. Technology assessment spans the
entire range of development activities. Parts (b), (e) and (f), source: Wikimedia. Part (c), source: Jupiter Images.
Part (d), source: NCI/Lindia Bartlett. Part (g), source: NCI/Michael Anderson.

cal testing in cell or animal models, as well as testing in The Littenberg method of technology
human subjects. These tests must be carried out in an assessment
ethical manner. In addition, an important consideration Benjamin Littenberg proposed a model of technology
in the adoption of new technologies is whether they are assessment that is particularly useful for new technolo-
cost effective. The process of health technology assess- gies. The Littenberg method asks five questions
ment spans all the steps in the healthcare technology regarding a new medical technology.
development process, from lab to patient.
! Biologic plausibility: does our current understanding

Learn more about the Littenberg method of the biology of the disease in question support the
use of the technology?
! Technical feasibility: can we safely and reliably deliver
The Littenberg method of technology assessment is
defined in this article and used to analyze screening
the new technology to the target patients?
! Clinical Trials: do the results of randomized clinical
tests for hypercholesterolemia.
Littenberg, B. Technology assessment in
medicine. Academic Medicine, 67(7), 424–428. trials comparing the new technology to current stan-
dards of care show a benefit?
 Bioengineering and technology assessment 23

! Patient outcomes: are patients better off for having
used the new technology?
! Societal outcomes: what are the costs and ethical
implications of the technology?

It is useful to consider our case study of HDCT+BMT
in the context of the Littenberg model to see whether
the technology was assessed appropriately at each level
and whether that assessment supports the use of the
technology.
Biologic plausibility: many scientific studies sup-
ported the promise of HDCT+BMT. In particular, as the
dose of chemotherapeutic agent was increased to treat
women with breast cancer, response rates increased.
Based on these data, physicians believed patients with
advanced breast cancer would benefit from doses of
chemotherapy so high that it would destroy bone mar-
row.
Technical feasibility: mortality rates were initially
quite high for breast cancer patients treated with
HDCT+BMT, despite the advances in leukemia treat-
ments showing that bone marrow transplantation could
be safely performed. However, as more women were Figure 2.2. Multiple clinical trials have proven mammography to be
treated and regimens were refined, mortality rates effective for screening for breast cancer in women. CDC.
dropped substantially, improving technical feasibility.
Thus initially HDCT+BMT was supported by both bio- apy; later trials examined survival. In assessing patient
logic plausibility and technological feasibility, the first outcomes it is important to consider both short term
two criteria of Littenberg’s method. outcomes (e.g. response rates) and long term outcomes
Clinical trials: there were many small, clinical trials (e.g. survival) as well as quality of life issues. Clearly,
carried out to assess the effectiveness of HDCT+BMT; patients treated with HDCT+BMT experienced a quality
however, these trials were not randomized clinical tri- of life that was initially lower because of the side effects
als. As we will see later, a randomized clinical trial is the of the treatment. In the end, randomized trials showed
strongest source of scientific evidence to assess whether that survival rates were not substantially higher than
a new technology is effective compared to current stan- those for standard treatment.
dards of care (Figure 2.2). The tragedy of HDCT+BMT Societal outcomes: was society better off for hav-
was the delay of completing randomized clinical trials, ing used HDCT+BMT? The new technology was sub-
due to political and media pressures and scientific mis- stantially more expensive than standard chemother-
conduct. By the time clinical trial results seriously ques- apy while adding no additional survival benefit. If
tioning the benefit of HDCT+BMT compared to stan- HDCT+BMT had showed clinical benefit compared to
dard chemotherapy were available, many women had standard therapy, then society would have to consider
already undergone the treatment. the difficult question of whether the increased benefit is
Patient outcomes: were women better off in the long worth the additional cost.
term for having been treated with HDCT+BMT? The Thus, HDCT+BMT was not supported by the final
early clinical trials assessed only response rates to ther- three criteria of the Littenberg method, a conclusion
24 Biomedical Engineering for Global Health

Challenges of anti-retroviral
drugs: June 13, 2007
Rachel Botswana
As we will see in Chapter 4, patients who are HIV positive are treated with drugs called anti-retrovirals or
ARVs. Often, patients must follow complex regimes of drugs. The situation is further complicated for
HIV positive children, because drug companies currently do not make ARVs in pediatric doses. So often
parents must split pills in half to ensure their children receive the correct dosage. Patients must adhere closely to the schedule
of taking their ARVs or HIV can develop resistance to the drugs. This is a major challenge in treating HIV/AIDS today.
I was thinking of different ways to help AIDS patients and I thought that a seven-day AM/PM pillbox would be useful. (I have
used them, and I remember my grandmother used them for her multitude of pills.) Then at the beginning or end of every
week, the patient or the caretaker can put all the pills (and half pills) in the proper compartments. Although this unfortunately
excludes all the people who need to take syrups, I was talking
with one of the patients who came in for a guide yesterday
about adherence and she said it would help. She has a son in his
teenage years and, while she gives him the pills most of the
days, sometimes he goes out to play football (soccer) with his
friends and forgets to take the pills with him. When I asked
about how he would feel carrying around a pill box, and if he
was comfortable taking it around his friends, she said that he
didn’t mind and that some of his friends were on ARVs as well.
I am getting a mixed view on exactly how prevalent or
entrenched the stigma for AIDS really is. Driving down from
Choebe this weekend, even in the smaller towns there were
billboards about AIDS encouraging testing, a large ad for
condoms, and a free condom box at the passport immigration.
I also saw the first abstinence billboard, which seemed almost to
contradict the “get tested” billboard on the opposite side of it.

that puts the effectiveness of the technology in serious or treatments as well as systems that aid in the delivery
doubt. Clearly, HDCT+BMT technology was not ade- of healthcare. The technology can address any com-
quately assessed before entering widespread use, a fail- ponent along the healthcare continuum: prevention,
ure that led to many women receiving a painful treat- screening, diagnosis, treatment, or rehabilitation. In
ment that offered fewer benefits than initially believed. this text you will see examples of technologies ranging
from simple childhood vaccinations to prevent disease
Important vocabulary of technology to complex total artificial hearts to treat end stage heart
assessment disease. While the complexity of the technology can dif-
In the rest of this chapter, we will outline in more detail fer dramatically, the process of healthcare technology
the methods of technology assessment. They will guide assessment is the same.
our thinking as we examine new technologies through- The ultimate goal of health technology assessment is
out the rest of the text. We begin with definitions of to inform decision making, whether it is done from the
some important terms. Technology does not necessar- perspective of an individual patient or from the larger
ily involve sophisticated or expensive James Bond like perspective of society. The underlying questions which
gadgetry or devices. Healthcare technology can be any health technology assessment needs to address include
intervention to promote health, including specific tests the following.
 Bioengineering and technology assessment 25

Prevention: health interventions designed to Examples of benefits and costs of prostate
prevent a patient from developing disease. cancer screening
Screening: a test given to members of a defined Monitoring the level of prostate specific antigen
population, not necessarily at risk for a disease, (PSA) is frequently used to screen older men to
to identify those individuals who are most likely determine if they are likely to have prostate cancer.
to be helped by further tests to diagnose the Invasive diagnostic testing is performed to
disease. determine whether men with elevated PSA levels
Diagnosis: the identification of disease through have prostate cancer requiring therapy.
signs, symptoms, imaging, bloodwork, cultures,
Intended benefits: screening can identify men
cytologic sampling, or biopsy.
with prostate cancer at an early stage, when it
Treatment: a health intervention to cure disease or
is still curable.
to reduce symptoms of disease.
Intended costs: the cost of a PSA exam is less
Rehabilitation: the process of restoring skills lost to
than $100.
illness or injury.
Unintended costs: because prostate cancer
grows slowly, the new test can identify men
with prostate cancer that will never cause any
! What is the clinical impact of the intervention? symptoms. These men undergo further
! What is the cost of the intervention? invasive, painful testing and treatment which
! What is the clinical impact of the intervention may be unnecessary.
weighed against its cost?

In order to answer these questions, it is necessary to
evaluate the safety, effectiveness, cost effectiveness, and. Let’s imagine that our screening test is somewhat
the social, ethical, and legal impacts of a technology. invasive and patients perceive it to be much more
In this evaluation, we must consider both the direct and uncomfortable than the previous screening test. As a
indirect consequences of using a health technology. result, some patients who would have been screened
Direct consequences of a health technology are the with the old test now avoid cancer screening altogether,
intended benefits and costs. For example, if we because of fear or embarrassment. In this case, the intro-
develop a new, more accurate cancer screening test, the duction of a new and more accurate test can actually
intended benefits