PMLS 1 Lecture Topics 1 and 2 PDF

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This document provides an introduction to medical technology, including its application, professionals, and history. It details different aspects of medical technology, including diagnostic procedures, laboratory practices, and historical figures.

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INTRODUCTION TO MEDICAL TECHNOLOGY

MEDICAL TECHNOLOGY/MEDICAL LABORATORY SCIENCE

The application of procedures, information and devices to develop highly
sophisticated solutions to medical problems or issues as the prevention of disease
or the promotion and monitoring of good health.
Refers to diagnostic or therapeutic application of science and technology to
improve the management of health conditions.
Combines the challenges of medicine, the basic sciences of biology and chemistry,
and the clinical sciences into a very satisfying professional career; study and
practice of diagnostic medicine.

MEDICAL TECHNOLOGIST/CLINICAL LABORATORY SCIENTIST

Are medical investigators, performing sophisticated analyses using state of the art
instrumentation to generate accurate test results.
Involved in all phases of sample analysis, direct and supervise laboratory
operations, as well as, collaborate in the diagnosis, care, and treatment of patients.
Perform complex chemical and biological, hematological, immunologic,
microscopic, and bacteriological tests.
Microscopically examine blood and other body fluids, make cultures of body fluids
and tissue sample to determine the presence of bacteria, fungi, parasites, or other
microorganisms; analyze sample for chemical content or a chemical reaction and
determine concentrations of compounds such as blood glucose and cholesterol
levels; type and cross match blood samples for transfusion.

HISTORY OF MEDICAL TECHNOLOGY PROFESSION IN THE PHILIPPINES AND
ABROAD

Early Beginnings:

In 460 BC, Hippocrates, a Greek physician regarded as the founder of scientific
medicine, determined the correlation between anatomical and chemical
laboratory findings and the causes of diseases. He adopted the triad of regimen
with the use of drugs, surgery, and bloodletting in treating diseases and
infection.
Early 1550 BC, Vivian Herrick determined parasitic infection caused by Ascaris
lumbricoides and Taenia species (published in a book by Ebers Papyrus).
In the same year, Anenzona, an Arabian physician, proved that parasites are
the etiological agent of skin diseases, such as scabies.
 During the Medieval period (1098-1438), Professor Ruth Williams mentioned
in the book “An Introduction to the Profession of Medical Technology” that
Urinalysis was a fad. During this period, some doctors of dubious credentials
in the Indian subcontinent recorded several observations and determined that
urine of certain patients that attracted ants had a sweet taste.
14th century, Anna Falgelson – a prominent Italian physician at the University
of Bologna employed Alexander Gillani to perform tasks considered to be that
of a medical technologist. Unfortunately, Gillani died of a laboratory acquired
infection.
17th century (1632-1723) – Anton Van Leeuwenhoek invented the first
functional crude microscope. The first scientist to observe and describe the
appearance of red blood cells and to differentiate bacteria based on their
shape.
In the 18th century, medical practitioners in North Africa and Southern Europe
received classical medical education.
Between 1821-1902, Rudolf Virchow was recognized as the Father of
Microscopic Pathology. The first scientist/physician who emphasized the study
of the manifestation of diseases and infections, which are visible by means of
a microscope at the cellular level.
Dr. Calvin Ellis, a microscopist at the Massachusetts General Hospital – the
first to utilize the microscope in examining specimens in the process of
evaluating disease and infections.
Dr. William Occam – used laboratory findings as preliminary evidence in
diagnosing and evaluating a patient’s disease.
Baron Karl Von Humboldt – initiated and formulated the Apothecaries Act of
1815, formally used laboratory findings in the treatment of diseases and
infections throughout England and Wales. The Act required instruction in
anatomy, botany, chemistry, material medical, and “physic,” in addition to six
months of practical working experience in a hospital.

Medical Technology on its Modern Era in the United States:

Emergence of clinical laboratories in the US occurred in the late 19th century.
In 1858, all part-time clinicians were reinforced as teachers by whole time
professional units applying the new laboratory methods to medical practice and
medical teaching at the University College at Cambridge.
United States – science was highly developed through medical education
reforms.
In 1871, Harvard University introduced reforms emphasizing on “learning by
doing”, followed by the University of Pennsylvania and the University of
Michigan.
 Opening of John Hopkins School of Medicine – provided two years of
instruction in the basic sciences.
In the late 1870’s, William H. Welch and Michell Prudden along with their
students – the first to apply clinical pathology to medical diagnosis.
In 1878, Dr. William H. Welch established another laboratory at the Bellevue
Hospital Medical College which he used for teaching and giving microscopical
courses. In 1885, Dr. Welch became the first professor of pathology at John
Hopkins University.
In 1880, Dr. William Osler – a clinical professor at the University of
Pennsylvania Hospital, introduced and used the microscope and blood
counting machine in the hospital-based laboratory; however, these instruments
were not well understood by physicians.
A few years later, first laboratory was opened – the largest and best-equipped
(chemical laboratory related to medicine) at the University of Michigan. Dr.
Douglas was the first to give laboratory instructions.
In 1887, the University Hospital in Philadelphia was established and built by Dr.
Douglas with the help of Dr. Osler and Dr. George Dock and then later at the
University Hospital in Ann Arbor. They ordered and mandated all patients to
undergo routine laboratory examinations, including urinalysis and blood
examinations.
In 1896, the first clinical laboratory was opened by Dr. William Osler at John
Hopkins Hospital (12x12 size room and was equipped at a cost of fifty dollars).
According to Comac’s article, William Pepper Laboratory – a clinical laboratory
had been opened at the University of Pennsylvania in 1896.
In 1900, census of the US listed 100 male technicians – evidence that clinical
laboratories had been established in 1896. This increased to 3,500 in 1920. In
1922, there were 3,035 hospitals that had clinical laboratories.
1908 – publication of a laboratory guide by Dr. James C. Todd – “Manual of
Chemical Diagnosis” – later with Dr. Arthur Stanford published a book entitled
“Clinical Diagnosis by Laboratory Methods” – edited by Davidson and Henry.
This book became the reference for laboratories.
1911 – complete revolution in the development of laboratory science was
formally approved by the Insurance Act as the basis of diagnosing diseases.
Eventually in 1915, the State Legislature of Pennsylvania enacted a law
requiring all hospitals and institutions to have complete laboratory facilities with
full–time technicians.
In 1940, US required a standard two-year curriculum on collegiate education
with one-year actual training in the laboratory for the preparation on its practice.
The said education led to a Bachelor of Science degree.
 World War I was an important factor in the growth of the clinical laboratory and
produced great demands for technicians.

Medical Technology in the Philippines:

World War II occurred from 1939-1945. On December 7, 1941 Pearl Harbor
was invaded by Japan. Three days after, Japan invaded the Philippines
causing wrath of the US to flare up. Sickness and death due to illness were
rampant.
In 1944, US bases were built in Leyte. US brought members of the healthcare
team to the Philippines to resolve the health problems of soldiers and Filipinos.
At the end of World War II, the first clinical laboratory in the Philippines “26 th
Medical Laboratory of the 6th United States Army” was built and located at
Quiricada Street, Sta. Cruz, Manila.
February 1944, the 26th Medical Laboratory provided one year training to high
school graduates to work as laboratory technicians.
June 1945 – the staff of the 26th Medical Laboratory of the 6th US Army left the
facility after endorsing the newly established Clinical Laboratory to the National
Department of Health.
Dr. Pio de Roda, a well-known Filipino bacteriologist, took the effort to preserve
the remnants of the said laboratory with the help of Dr. Mariano C. Icasiano
(the first City Health Officer of Manila).
Dr. Mariano C. Icasiano, accepted the proposal of Dr. de Roda to establish a
laboratory under the city health department.
October 1, 1945 – a medical laboratory (Public Health Laboratory) was formally
organized and re-established by Dr. Pio de Roda with the help of Dr. Prudencio
Sta. Ana.
1947 – free training of medical technicians (who were high school graduates
and paramedical graduates) started under Dr. de Roda and Dr. Prudencio Sta.
Ana.
1954 – Dr. de Roda instructed Dr. Sta. Ana to prepare a syllabus for training
medical technicians; a six-month training period was required and a certificate
was issued to successful trainees.
Dr. Tirso Briones later joined the two doctors.
1954 – The first four-year B.S. Medical Technology course was offered by
Philippine Union College of Baesa, Caloocan, Rizal (now located in Silang,
Cavite) through its sister company Manila Sanitarium Hospital.
Dr. Jesse Umali, the first student who graduated, later went on to pursue
studies in medicine and became an OB-gynecologist and owner of Omega Lab.
 Dr. Willa Hilgert Hedrick – founder of Medical Technology Education in the
Philippines and an American medical practitioner and missionary of the
Seventh Day Adventist.
Dr. Hedrick, with the help of Mrs. Antoinette McKelvey, prepared the course
curriculum; established the first complete laboratory in Microbiology,
Parasitology, and Histopathology at the Manila Sanitarium Hospital.
1957 – Dr. Antonio Gabriel and Dr. Gustavo Reyes of the UST Pharmacy
offered an elective to pharmacy graduates leading to the Medical Technology
course.
1960-1961 – The Bureau of Education officially approved the first three-year
academic course and the year as an internship program.
1960 – Centro Escolar University delegated Purificacion Sunico-Suaco to work
on offering the medical technology course. The recognition permit was later
granted by the Bureau of Education and had its first batch of graduates two
years later.
1961 – Far Eastern University started its school of Medical Technology.
Followed by several colleges and universities throughout the country which
began offering the Bachelor’s degree in Medical Technology.
 NATURE AND SCOPE OF MEDICAL TECHNOLOGY/
MEDICAL LABORATORY SCIENCE
(see SUBA et al, CHAPTER 1, pp. 18-21)

The Multifaceted Nature of Medical Technology
Substantial Procedural – a Procedure of Scientific Activities
Medical Technology uses a wide range of technologies to diagnose certain
diseases and infections. Such technologies include the use of an autoanalyzer in
sophisticated tertiary category, flow cytometry in histopathology, and high-
performance chromatography for drug analysis. All laboratory methods comprise
scientific procedures, irrespective of whether the technology is conventional or
automated.

Investigative Complicity – a Paramount Field of Scientific Investigation
Medical technology encompasses scientific inquiry of various societal health
problems and involves a wide range of laboratory investigations. These laboratory
investigations include drug testing to rule out drug addiction, molecular and nucleic
acid analysis for genetic disease diagnosis, forensic investigation, and scientific
research.

Intermedical Procedural Interference – an Intervention in Medical Procedures
In every aspect of medical procedures, a physician always resorts to the laboratory
findings in giving the right prognosis of diseases and infections. For example, a
bacterial infection mandates a microbiological analysis. Following this procedure, the
assigned medical technologist may provide scientific findings supporting the use of
specific antibiotics that may be prescribed by the physician.

Assiduous Partner – an Explicit Application of Science and Technology
Medical technology embraces the techniques and procedures laid down by
science and technology. For example, the use of polymerase chain reaction is used
for deoxyribonucleic acid (DNA) amplification. Similarly, use of high-performance
liquid chromatography or an automated instrument to detect for presence of certain
drugs is another example of practical application of medical technology procedure.

Circumstantial Medical Evidences – Evidentiary Information in Medicine
Medical technology services assist physicians and healthcare providers. The
laboratory findings serve as proof of the medical findings and prognosis. For this
purpose, medical technology is the clinical eye of physicians. One good example is
when blood glucose determination has been conducted and the laboratory results
reveal that the patient is hyperglycemic because the blood glucose concentration is
above the upper limit of the reference values; it can then be established as evidentiary
 information that the patient might be diabetic. Moreover, the finding of hyperglycemia
is then correlated with the clinical manifestation as observed and diagnosed by the
physician.

Medical Technology as a Prelude to Biomedical Research

Instrument Selection, Operation, Maintenance, and Troubleshootings
It is mandatory in the field of medical technology that instrumentation must include
the entire process of selection, operation, maintenance, and troubleshooting. The life-
blood theory offers an explanation for this basic knowledge in instrumentation,
especially in bioresearch, particularly in dealing with cell culture and stem cell therapy
and management. A clinical laboratory cannot exist without these technologies. It is
through these instrumentations that clinical laboratories can be of service to patients
in need.

Utilization of a Computerized Information System for Data Input, Retrieval, and
Analysis
Automation and computer literacy is the mantra of the present generation.
Automation extends to clinical laboratories as well, especially those laboratories
employing LIS where services are offered through networking.

Quality Control, Quality Assurance, and Performance Improvement
Quality control and assurance have been established in every aspect of clinical
laboratory. It is usually carried out using a set of standard, control, and pooled sera
for clinical chemistry purposes and is performed daily, weekly, or monthly depending
on the working status of the instrument; viability of the reagents and chemicals; in
case of a new procedure, especially when proposing bioresearch projects; or when
the medical technologist is a new hire or the researcher is proposing the applicability
of the proposed research procedure.

Inventory Control
A set of laboratory procedures are used for all bioresearch procedures. The
inventory of procedures and instruments to be used control the entire flow of
bioresearch. Without this inventory, one cannot ensure the projection of accurate and
reliable results. For example, while culturing green algae, the inventory of materials
and procedures to be used determine the feasible attainment of bioresearch
objectives.
 Clinical Trials
Clinical trials are the most important concerns of bioresearch. Clinical trials are
mandatory steps, especially during the process of proving that efficacy and
effectiveness of the proposed vaccines or herbal plants, for example. These clinical
trials are performed in clinical laboratories. Therefore, good instrumentation,
component technologists, and standardized procedures are required.

The Scope of Medical Technology

Investigating Nosocomial Infections
Patients typically contract a nosocomial infection during a prolonged hospital stay.
The process of investigation is within the function of medical technology. The
investigation is usually carried out by microbiological analysis through isolation and
identification. Once the causative agents have been identified, the next step is to
perform culture and susceptibility testing, which then help determine which broad-
spectrum antibiotic may inhibit or kill the causative agents of infection.

New Discoveries Through Research
Scientific research offers innovative techniques and technology, which is pivotal to
the role of Medical Technology.

Including Medical Technology in Public Health Education Through Seminar/
Workshops
As a health practitioner, the medical technologist imparts education as mandated
by the Commission on Higher Education in Philippine setting or Ministry of Health in
other Asian countries such as Hong Kong.

Extending Services to Molecular Engineering
Within the ambit of medical technology service function, it is noteworthy to mention
that molecular genetics or molecular engineering such as gene therapy, diagnosis,
and screening have been embraced in the field of medical technology.

Pioneer in Laboratory Medical Diagnostic Services
Medical technology employs diagnostic procedures.

Evaluating the Efficacy of Drug Treatment Through Microbiological Analysis
The department of microbiology deals with microbiology analysis, including the
identification of microbes, through culture and staining morphology, biochemical
properties and reaction, and performing quality control procedure or monitoring.
 Engaging in Blood Donation and Bloodletting Services for the Public
It is within the function of medical technology to screen blood donors, and perform
cross matching and blood typing before blood transfusion.

Laboratory Diagnosis
Laboratory diagnosis involves a series of procedural methods that are performed
in a clinical laboratory. It employs sophisticated methods or procedures, wherein the
findings can be potential evidence in evaluating the health status of the patient.

Biological and Medical Research
So, in terms of scientific research, medical technology as a laboratory medicine,
can provide solutions to health problems and issues.

Prevention and Control of Diseases and Infection
Medical technology serves as a clinical eye of a medical doctor, and provides
information on the prevention and control of diseases and infection.

Innovative Techniques and Technology
Medical technology encompasses innovative techniques and technologies in
laboratory diagnosis. It has pioneered new technologies and techniques to provide a
wide spectrum of laboratory services.
 ROLES OF MT/MLS PROFESSION IN THE DIAGNOSIS
AND TREATMENT OF DISEASE
(see SUBA et al, CHAPTER 2, pp. 32-33)

Examination of Laboratory Specimens
Registered medical technologists assigned to a clinical laboratory are equipped
with technical skills and theoretical knowledge to examine samples of blood and other
body fluids for the determination of blood chemical constituent concentrations (blood
chemical constituent analysis); presence or absence of parasitic ova, larva, and adults
(fecalysis); the detection of urine chemicals and formed elements (urinalysis); the
identification of microbes and antibiotic reactions (microbiological analysis); the
testing of blood compatibility (cross matching); the detection and identification of
abnormality (histopathological analysis); the detection of antigen and antibody
reaction in vitro (serological analysis); and the determination of blood formed element
levels (hematological analysis). After performing laboratory examinations, the results
are submitted to the chief pathologist for review before they are recorded and
released.

Setting and Implementing a Quality Control Program
Every section in a clinical laboratory must have its own quality control program and
implementation is usually done periodically. In addition, the quality control procedure
in a school-based laboratory may include the standardization of solutions, calibration
of instruments and apparatuses.

Setting and Implementing Laboratory Safety Measures
As a mandate, all registered medical technologists must set and practice
laboratory safety measures in a clinical laboratory. This work is more transparent in a
school-based laboratory than clinical laboratory because the students are affected to
a greater extent, not being fully aware of the laboratory safety procedures. This is
unlike in a clinical laboratory, where laboratory safety procedures are well
disseminated to all practicing medical technologists through a work orientation session
prior to their hiring and assuming their positions in the laboratory.

Regular Calibration of Instruments and Equipment
This is required to test the workability of the instruments. The instruments are
calibrated by the supplier annually. They include the spectrophotometer,
autoanalyzer, electrophoresis apparatus, autoclave, incubator in both school-based
and hospital-based laboratories. It is necessary for the medical technologists to record
the calibration period and the name and credentials of the person calibrating the
instruments.
 Operation of Laboratory Instruments Ranging from a Simple Microscope to Complex
Automated Equipment
These operations and manipulations of instruments are routine for medical
technologists, whether it is part of their daily work or a case of troubleshooting. The
onus is on the assigned medical technologist to report major issues, such as defective
instruments, to the supplier’s technical team, and also to the pathologist or concerned
program head.

Conducting of Research Activities and Exploration of New Discoveries in the Field of
Science and Biotechnology
Research activities done by medical technologists assigned to a school-based
laboratory are carried out for professional growth. They also assist medical technology
students in doing their undergraduate thesis. The involvement of the medical
technologists in research activities is usually supported by the institution, as the
research outcome should benefit the entire institution concerned.

Collection of Laboratory Specimens for Examination
As a standard operating procedure in a clinical laboratory, the medical technologist
should observe the right protocol in specimen collection and processing. Moreover, in
a school-based setting, the collection of specimens is usually carried out by the
students, but under the supervision of their professors who are also registered medical
technologists. The specimens collected are usually the subject of the experimentation
in a school-based laboratory, and these include blood, feces, urine, saliva, and
microbial cultures. Precautionary measures are observed during such
experimentation; the handling and management of laboratory specimens are
monitored by the government agency affiliated with the concerned institution.