This article possibly contains original research .(July 2024) |
Paul R. Billings, MD, Ph.D., FACP, FACMGG | |
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Citizenship | American |
Education | 1970-1972: U.C. Santa Cruz 1972-1974: A.B. at U.C. San Diego (summa cum laude) 1974-1979: M.D. at Harvard Medical School 1976-1979: Ph.D. Immunology, Harvard University Graduate School of Arts and Sciences (Baruj Benacerraf, MD Thesis Supervisor)Contents |
Occupation(s) | CEO and Director of Biological Dynamics, Inc., Co-Founder and Chairman of Plumcare LLC, Chairman of Synergenz Bioscience Limited, Co-Founder and Senior Medical Advisor of FabricGenomics, Inc., and Director of DecisionQ Inc., ProterixBio, and PAX Neuroscience Inc. |
Known for | Interest in genomic diagnostics for medical care and coining the term “individualized” genomic medicine. |
Awards | Harvard Medical School's James Tolbert Shipley Prize for best-published research in 1979. Received research grants and awards for his work from various organizations. |
Dr. Paul R. Billings is a distinguished American doctor, lecturer, researcher, professor, and consultant on genetic information. His research interests include the impact of genomic data on society, the integration of genomics with diagnostics in health and medical care, and individualised genomic medicine. He is the author of over 250 publications and has appeared on talk shows such as The Oprah Winfrey Show and 60 Minutes. He is currently the CEO and Director of Biological Dynamics.
Dr. Billings is a board-certified internist and clinical geneticist known for his extensive expertise in genomics and molecular medicine that spans more than 40 years. Dr. Billings has helped many notable organisations, including roles with the Scientific Advisory Board of the Food and Drug Administration (FDA) and the Genomic Medicine Advisory Committee at the Department of Veterans Affairs. He also served as a member of the United States Department of Health and Human Services’ secretary's advisory committee on genetics, health, and society. He was formerly a director of the Personalised Medicine Coalition and a member of the IOM Genomics Roundtable, helping to make an impact on healthcare for broad populations.
Dr. Billings is the CEO and Director at Biological Dynamics, a company dedicated to improving global health outcomes by identifying early-stage disease through its proprietary exosome diagnostic technology. [1] Its ExoVerita platform offers a simple and automated workflow to capture and analyse exosomes, powering advanced detection tests for myriad complex diseases. This technology utilises the ExoVerita platform to enable reliable surveillance and early cancer detection to increase the chance of survival for patients.
Prior to his CEO role at Biological Dynamics, Dr. Billings was the Chief Medical Officer at Natera, Inc., a leader in cell-free DNA testing. Prior to that, he completed an Executive-in-Residence programme at the California Innovation Centre of Johnson & Johnson, was a consultant for Quest Diagnostics Inc., and served as the medical director of the IMPACT Cancer Care Programme at Thermo Fisher Scientific (TFS). Dr. Billings also held key roles at MissionBio, Life Technologies Inc. (LIFE), and the Genomic Medicine Institute, located at El Camino Hospital, the largest community hospital in Silicon Valley.
Dr. Billings founded and led a number of companies focused on genetic and diagnostic medicine throughout his career, including Omica/FabricGenomics, GeneSage Inc., and Cellective Dx Corporation. He has held academic appointments at prestigious institutions, including Harvard University, the University of California, San Francisco, Stanford University, and the University of California, Berkeley. Notably, his work on genetic discrimination played a crucial role in creating and passing the federal Genetic Information Non-Discrimination Act of 2008. From 2003 to 2007, he was senior vice president for corporate development at Laboratory Corporation of America Holdings (NYSE: LH).
He served as a director of Ancestry.com (NASDAQ: ACOM) before their recent transactions, executive chairman of Signature Genomics Laboratories, LLC, and founder of the Cord Blood Registry, Inc. Previously, he served as a board director of TrovaGene, Inc., and CollabRX, Inc., both publicly traded personalised medicine companies in the United States. He also acts as the chief medical officer of Fabric, Inc. Additionally, Dr. Billings has held positions on various other for-profit and not-for-profit boards, including the Council for Responsible Genetics, Cancer Commons, and the Ronald McDonald House Charities (Bay Area).
Dr. Paul R. Billings has a diverse educational background, beginning at the Webb School of California in the 1960s. He pursued his undergraduate studies at the University of California, Santa Cruz, in 1970 before transferring to the University of California, San Diego, in 1972. While at UCSD, Dr. Billings had the opportunity to work as a student fellow at the Salk Institute of Biological Sciences under the guidance of adviser Dr. Martin Kagnoff. In 1973, he served as a student summer fellow at the American Gastroenterology Association, advised by Dr. Morton Grossman.
In 1974, Dr. Billings graduated summa cum laude from UC San Diego with an Artium Baccalaureatus (AB) Degree in History. He then continued his education at Harvard University, where he pursued medicine and immunology as a recipient of the Medical Scientist Training Grant Fellowship from the National Institutes of Health (NIH) and Harvard University. His research at Harvard earned him the James Tolbert Shipley Prize for best-published research in 1979. That same year, Dr. Billings obtained a Ph.D. in immunology and an M.D. degree. [2]
During his time at Harvard, his Ph.D. supervisor was Baruj Benacerraf, who won a Nobel Prize the following year in 1980.
Following medical school, Dr. Billings began his residency at University of Washington-affiliated hospitals, which he completed in 1982. He then continued as a fellow in medical genetics under the guidance of Dr. Arno Motulsky until 1984. In subsequent years, Dr. Billings held teaching and tutoring positions at renowned institutions such as the University of California, Berkeley, Harvard University, the University of California, San Francisco, and Stanford University.
Dr. Billings’s research focuses on the intersection of ethics and medicine. He explores the societal impact of genetic information and biotechnology, the integration of genomics into healthcare, post-genomic health and identity, molecular biology, immunogenetics, their relationship to cellular differentiation, their application in cancer care, and human stem cell research in clinical medicine. Various organisations have funded his groundbreaking work, including the National Institutes of Health, the Robert Wood Johnson Foundation, and the Council for Responsible Genetics. [3]
Following is a partial list of Billings' government positions:
Billings on "Genetics news (www.geneletter.com)":
Gene therapy is a medical technology that aims to produce a therapeutic effect through the manipulation of gene expression or through altering the biological properties of living cells.
A biopsy is a medical test commonly performed by a surgeon, an interventional radiologist, or an interventional cardiologist. The process involves the extraction of sample cells or tissues for examination to determine the presence or extent of a disease. The tissue is then fixed, dehydrated, embedded, sectioned, stained and mounted before it is generally examined under a microscope by a pathologist; it may also be analyzed chemically. When an entire lump or suspicious area is removed, the procedure is called an excisional biopsy. An incisional biopsy or core biopsy samples a portion of the abnormal tissue without attempting to remove the entire lesion or tumor. When a sample of tissue or fluid is removed with a needle in such a way that cells are removed without preserving the histological architecture of the tissue cells, the procedure is called a needle aspiration biopsy. Biopsies are most commonly performed for insight into possible cancerous or inflammatory conditions.
Comparative genomic hybridization (CGH) is a molecular cytogenetic method for analysing copy number variations (CNVs) relative to ploidy level in the DNA of a test sample compared to a reference sample, without the need for culturing cells. The aim of this technique is to quickly and efficiently compare two genomic DNA samples arising from two sources, which are most often closely related, because it is suspected that they contain differences in terms of either gains or losses of either whole chromosomes or subchromosomal regions. This technique was originally developed for the evaluation of the differences between the chromosomal complements of solid tumor and normal tissue, and has an improved resolution of 5–10 megabases compared to the more traditional cytogenetic analysis techniques of giemsa banding and fluorescence in situ hybridization (FISH) which are limited by the resolution of the microscope utilized.
Medical genetics is the branch of medicine that involves the diagnosis and management of hereditary disorders. Medical genetics differs from human genetics in that human genetics is a field of scientific research that may or may not apply to medicine, while medical genetics refers to the application of genetics to medical care. For example, research on the causes and inheritance of genetic disorders would be considered within both human genetics and medical genetics, while the diagnosis, management, and counselling people with genetic disorders would be considered part of medical genetics.
Simpson–Golabi–Behmel syndrome (SGBS) is a rare inherited congenital disorder that can cause craniofacial, skeletal, vascular, cardiac, and renal abnormalities. There is a high prevalence of cancer associated in those with SGBS which includes wilms tumors, neuroblastoma, tumors of the adrenal gland, liver, lungs and abdominal organs. The syndrome is inherited in an X-linked recessive manner. Females that possess one copy of the mutation are considered to be carriers of the syndrome but may still express varying degrees of the phenotype, suffering mild to severe malady. Males experience a higher likelihood of fetal death.
Noninvasive genotyping is a modern technique for obtaining DNA for genotyping that is characterized by the indirect sampling of specimen, not requiring harm to, handling of, or even the presence of the organism of interest. Beginning in the early 1990s, with the advent of PCR, researchers have been able to obtain high-quality DNA samples from small quantities of hair, feathers, scales, or excrement. These noninvasive samples are an improvement over older allozyme and DNA sampling techniques that often required larger samples of tissue or the destruction of the studied organism. Noninvasive genotyping is widely utilized in conservation efforts, where capture and sampling may be difficult or disruptive to behavior. Additionally, in medicine, this technique is being applied in humans for the diagnosis of genetic disease and early detection of tumors. In this context, invasivity takes on a separate definition where noninvasive sampling also includes simple blood samples.
Digital polymerase chain reaction is a biotechnological refinement of conventional polymerase chain reaction methods that can be used to directly quantify and clonally amplify nucleic acids strands including DNA, cDNA, or RNA. The key difference between dPCR and qPCR lies in the method of measuring nucleic acids amounts, with the former being a more precise method than PCR, though also more prone to error in the hands of inexperienced users. PCR carries out one reaction per single sample. dPCR also carries out a single reaction within a sample, however the sample is separated into a large number of partitions and the reaction is carried out in each partition individually. This separation allows a more reliable collection and sensitive measurement of nucleic acid amounts. The method has been demonstrated as useful for studying variations in gene sequences — such as copy number variants and point mutations.
Victor E. Velculescu is a Professor of Oncology and Co-Director of Cancer Biology at Johns Hopkins University School of Medicine. He is internationally known for his discoveries in genomics and cancer research.
Septin-9 is a protein that in humans is encoded by the SEPT9 gene.
Cancer genome sequencing is the whole genome sequencing of a single, homogeneous or heterogeneous group of cancer cells. It is a biochemical laboratory method for the characterization and identification of the DNA or RNA sequences of cancer cell(s).
Natera, Inc. is a clinical genetic testing company based in Austin, Texas that specializes in non-invasive, cell-free DNA (cfDNA) testing technology, with a focus on women’s health, cancer, and organ health. Natera’s proprietary technology combines novel molecular biology techniques with a suite of bioinformatics software that allows detection down to a single molecule in a tube of blood. Natera operates CAP-accredited laboratories certified under the Clinical Laboratory Improvement Amendments (CLIA) in San Carlos, California and Austin, Texas.
Molecular diagnostics is a collection of techniques used to analyze biological markers in the genome and proteome, and how their cells express their genes as proteins, applying molecular biology to medical testing. In medicine the technique is used to diagnose and monitor disease, detect risk, and decide which therapies will work best for individual patients, and in agricultural biosecurity similarly to monitor crop- and livestock disease, estimate risk, and decide what quarantine measures must be taken.
Circulating tumor DNA (ctDNA) is tumor-derived fragmented DNA in the bloodstream that is not associated with cells. ctDNA should not be confused with cell-free DNA (cfDNA), a broader term which describes DNA that is freely circulating in the bloodstream, but is not necessarily of tumor origin. Because ctDNA may reflect the entire tumor genome, it has gained traction for its potential clinical utility; "liquid biopsies" in the form of blood draws may be taken at various time points to monitor tumor progression throughout the treatment regimen.
A liquid biopsy, also known as fluid biopsy or fluid phase biopsy, is the sampling and analysis of non-solid biological tissue, primarily blood. Like traditional biopsy, this type of technique is mainly used as a diagnostic and monitoring tool for diseases such as cancer, with the added benefit of being largely non-invasive. Liquid biopsies may also be used to validate the efficiency of a cancer treatment drug by taking multiple samples in the span of a few weeks. The technology may also prove beneficial for patients after treatment to monitor relapse.
CAPP-Seq is a next-generation sequencing based method used to quantify circulating DNA in cancer (ctDNA). The method was introduced in 2014 by Ash Alizadeh and Maximilian Diehn’s laboratories at Stanford, as a tool for measuring Cell-free tumor DNA which is released from dead tumor cells into the blood and thus may reflect the entire tumor genome. This method can be generalized for any cancer type that is known to have recurrent mutations. CAPP-Seq can detect one molecule of mutant DNA in 10,000 molecules of healthy DNA. The original method was further refined in 2016 for ultra sensitive detection through integration of multiple error suppression strategies, termed integrated Digital Error Suppression (iDES). The use of ctDNA in this technique should not be confused with circulating tumor cells (CTCs); these are two different entities.
Circulating free DNA (cfDNA) (also known as cell-free DNA) are degraded DNA fragments released to body fluids such as blood plasma, urine, cerebrospinal fluid, etc. Typical sizes of cfDNA fragments reflect chromatosome particles (~165bp), as well as multiples of nucleosomes, which protect DNA from digestion by apoptotic nucleases. The term cfDNA can be used to describe various forms of DNA freely circulating in body fluids, including circulating tumor DNA (ctDNA), cell-free mitochondrial DNA (ccf mtDNA), cell-free fetal DNA (cffDNA) and donor-derived cell-free DNA (dd-cfDNA). Elevated levels of cfDNA are observed in cancer, especially in advanced disease. There is evidence that cfDNA becomes increasingly frequent in circulation with the onset of age. cfDNA has been shown to be a useful biomarker for a multitude of ailments other than cancer and fetal medicine. This includes but is not limited to trauma, sepsis, aseptic inflammation, myocardial infarction, stroke, transplantation, diabetes, and sickle cell disease. cfDNA is mostly a double-stranded extracellular molecule of DNA, consisting of small fragments (50 to 200 bp) and larger fragments (21 kb) and has been recognized as an accurate marker for the diagnosis of prostate cancer and breast cancer.
Elective genetic and genomic testing are DNA tests performed for an individual who does not have an indication for testing. An elective genetic test analyzes selected sites in the human genome while an elective genomic test analyzes the entire human genome. Some elective genetic and genomic tests require a physician to order the test to ensure that individuals understand the risks and benefits of testing as well as the results. Other DNA-based tests, such as a genealogical DNA test do not require a physician's order. Elective testing is generally not paid for by health insurance companies. With the advent of personalized medicine, also called precision medicine, an increasing number of individuals are undertaking elective genetic and genomic testing.
Urinary cell-free DNA (ucfDNA) refers to DNA fragments in urine released by urogenital and non-urogenital cells. Shed cells on urogenital tract release high- or low-molecular-weight DNA fragments via apoptosis and necrosis, while circulating cell-free DNA (cfDNA) that passes through glomerular pores contributes to low-molecular-weight DNA. Most of the ucfDNA is low-molecular-weight DNA in the size of 150-250 base pairs. The detection of ucfDNA composition allows the quantification of cfDNA, circulating tumour DNA, and cell-free fetal DNA components. Many commercial kits and devices have been developed for ucfDNA isolation, quantification, and quality assessment.
Personalized genomics is the human genetics-derived study of analyzing and interpreting individualized genetic information by genome sequencing to identify genetic variations compared to the library of known sequences. International genetics communities have spared no effort from the past and have gradually cooperated to prosecute research projects to determine DNA sequences of the human genome using DNA sequencing techniques. The methods that are the most commonly used are whole exome sequencing and whole genome sequencing. Both approaches are used to identify genetic variations. Genome sequencing became more cost-effective over time, and made it applicable in the medical field, allowing scientists to understand which genes are attributed to specific diseases.
EPIC-seq,, is a high-throughput method that specifically targets gene promoters using cell-free DNA (cfDNA) sequencing. By employing non-invasive techniques such as blood sampling, it infers the expression levels of targeted genes. It consists of both wet and dry lab stages.