Varian Medical Systems

Last updated
Varian Medical Systems Inc.
Company type Subsidiary
Industry Medical Technology
Founded1948;76 years ago (1948)
Headquarters Palo Alto, California, U.S.
Key people
Arthur Kaindl, CEO [1]
Products Medical Devices
Revenue
  • Increase2.svg US$ 2,919.1 million (2018) [2]
  • Increase2.svg US$ 2,619.3 million (2017) [2]
  • Increase2.svg US$ 441.6 million (2018) [2]
  • Decrease2.svg US$ 300.2  million (2017) [2]
  • Decrease2.svg US$ 150.3 million (2018) [2]
  • Decrease2.svg US$ 219.2 million (2017) [2]
Total assets
  • Increase2.svg US$ 3,252.7 million (2018) [2]
  • Decrease2.svg US$ 3,179.4 million (2017) [3]
Total equity
  • Increase2.svg US$ 1,588.7 million (2018) [2]
  • Decrease2.svg US$ 1,499.3 million (2017) [3]
Number of employees
10,000 [2]
Parent Siemens Healthineers
Website www.varian.com

Varian Medical Systems is an American radiation oncology treatments and software maker based in Palo Alto, California. Their medical devices include linear accelerators (LINACs) and software for treating cancer and other medical conditions with radiotherapy, radiosurgery, proton therapy, and brachytherapy. The company supplies software for managing cancer clinics, radiotherapy centers, and medical oncology practices. Varian Medical Systems employs more than 7,100 people [2] at manufacturing sites in North America, Europe, and China and approximately 70 sites globally. [4]

Contents

In August 2020, Siemens Healthineers announced plans to acquire Varian for $16.4 billion. [5] [6] The deal was completed in April 2021. [7] After the merger Varian continues to operate independently; it retained its headquarters and employees. [8] [9]

History

Varian was founded in 1948 as Varian Associates by Russell H. Varian, Sigurd F. Varian, William Webster Hansen, and Edward Ginzton to sell the Klystron, the first tube which could generate electromagnetic waves at microwave frequencies, and other electromagnetic equipment. [10] [11]

By 1999, Varian Associates had branched into semiconductor, vacuum tube, and medical device fields. On April 2, 1999, these divisions split to become Varian Semiconductor, Varian, Inc., and Varian Medical Systems. [12] [13]

In August 2020, Siemens Healthineers announced plans to acquire Varian Medical Systems in an all-stock deal valued at $16.4 billion. [14] [15] The deal was approved and completed on 15 April 2021. [16]

Acquired companies

Before its acquisition by Siemens Healthineers, Varian Medical Systems had acquired other companies, including Pan-Pacific Enterprises, [17] ACCEL Instruments, [18] Bio-Imaging Research, Inc. [19] Sigma Micro Informatique Conseil, [20] Argus Software, [21] Dosetek Oy, [22] Velocity Medical Solutions. [23] and MeVis Medical Solutions AG. [24]

In January 2018, the company announced the acquisition of Sirtex Medical for $1.3 billion. [25]

In 2019, the company acquired CyberHeart, a privately held company with intellectual property (IP) that covers the use of radiation in the heart (cardiac radioablation) and other forms of radiosurgery for cardiovascular disease. [26]

Spin-off companies

Varex Imaging office in Santa Clara Varex Imaging office, Santa Clara.jpg
Varex Imaging office in Santa Clara

On January 30, 2017, a spin-off of Varex Imaging Corporation (manufacturing of X-ray imaging products) from Varian Medical Systems had been successfully completed. [27]

Products

Linear accelerators

Varian manufactures a range of megavoltage LINACs with varying levels of features and complexity, for example different numbers of multileaf collimators or the ability to perform radiosurgery. [28]

TrueBeam is a radiotherapy system. [29]

The EDGE radiosurgery suite was launched in 2012. [30] The first cancer centers to use the new system were the Champalimaud Foundation in Lisbon, Portugal, and Henry Ford Health System in Detroit, Michigan. [31]

Halcyon

In 2017, Varian launched Halcyon. The system features unique dual-layer MLC that enables high modulation with low leakage for every field or arc. Halcyon is advertised to be intuitive, friendly and comfortable for clinical staff and patient alike. This is primarily done by automating several functions typically performed manually by radiographers, such as switching between treatment beams automatically. Additionally, Halcyon also features an automated machine performance check for daily LINAC quality assurance, which can speed up the checking of beam constancy and mechanical performance through the use of a phantom. [32]

However, while Halcyon does boast improved automation and workflow improvements which allow for faster patient treatment, these extra automation tasks can make occasionally make it more difficult for medical physicists to perform detailed Quality Assurance on LINAC performance. Nevertheless, automation in both quality assurance and clinical operation generally make the LINAC easier to operate by checkers and radiation therapists.[ citation needed ]

Proton Therapy

Varian manufactures the ProBeam Proton Therapy System, with current and planned installations at several sites globally. [33] These are an all pencil-beam scanning proton therapy system utilizing IMPT (intensity modulated proton therapy), which was developed with PSI of Switzerland. [34] Varian also develops medical software and radiology information system for proton treatment planning system.

Ethos Therapy

On September 16, 2019, during the 2019 American Society for Radiation Oncology (ASTRO) annual meeting, being held Sept. 15–18 in Chicago, Varian announced Ethos therapy, an artificial intelligence (AI)-driven system designed to increase the capability, flexibility and efficiency of radiotherapy. This new system is designed to deliver an entire adaptive treatment in a typical 15-minute timeslot, from patient setup through treatment delivery.[ citation needed ]

Litigation

Defamation case law

In 1999, Varian Medical Systems, Inc. sued a former employee for defamation after they posted numerous messages criticizing the company on the Internet. [35] The lawsuit led to the ruling of Varian v. Delfino by the California Supreme Court on the question whether a trial could proceed while denial of the defendant's anti-SLAPP motion was under appeal. After the state supreme court ruled that a new trial would be necessary because of that technical concern, [36] the case was settled on undisclosed terms.

University of Pittsburgh

On April 25, 2012, a US federal judge in Pittsburgh awarded attorney fees, costs, and doubled damages totaling $73.6 million to the University of Pittsburgh after the university won a suit on medical patent infringement grounds against Varian. [37]

Related Research Articles

<span class="mw-page-title-main">Radiation therapy</span> Therapy using ionizing radiation, usually to treat cancer

Radiation therapy or radiotherapy is a treatment using ionizing radiation, generally provided as part of cancer therapy to either kill or control the growth of malignant cells. It is normally delivered by a linear particle accelerator. Radiation therapy may be curative in a number of types of cancer if they are localized to one area of the body, and have not spread to other parts. It may also be used as part of adjuvant therapy, to prevent tumor recurrence after surgery to remove a primary malignant tumor. Radiation therapy is synergistic with chemotherapy, and has been used before, during, and after chemotherapy in susceptible cancers. The subspecialty of oncology concerned with radiotherapy is called radiation oncology. A physician who practices in this subspecialty is a radiation oncologist.

<span class="mw-page-title-main">External beam radiotherapy</span> Treatment of cancer with ionized radiation

External beam radiation therapy (EBRT) is a form of radiotherapy that utilizes a high-energy collimated beam of ionizing radiation, from a source outside the body, to target and kill cancer cells. A radiotherapy beam is composed of particles which travel in a consistent direction; each radiotherapy beam consists of one type of particle intended for use in treatment, though most beams contain some contamination by other particle types.

<span class="mw-page-title-main">Megavoltage X-rays</span> High energy (>1MeV) X-rays

Megavoltage X-rays are produced by linear accelerators ("linacs") operating at voltages in excess of 1000 kV (1 MV) range, and therefore have an energy in the MeV range. The voltage in this case refers to the voltage used to accelerate electrons in the linear accelerator and indicates the maximum possible energy of the photons which are subsequently produced. They are used in medicine in external beam radiotherapy to treat neoplasms, cancer and tumors. Beams with a voltage range of 4-25 MV are used to treat deeply buried cancers because radiation oncologists find that they penetrate well to deep sites within the body. Lower energy x-rays, called orthovoltage X-rays, are used to treat cancers closer to the surface.

<span class="mw-page-title-main">Proton therapy</span> Medical Procedure

In medicine, proton therapy, or proton radiotherapy, is a type of particle therapy that uses a beam of protons to irradiate diseased tissue, most often to treat cancer. The chief advantage of proton therapy over other types of external beam radiotherapy is that the dose of protons is deposited over a narrow range of depth; hence in minimal entry, exit, or scattered radiation dose to healthy nearby tissues.

<span class="mw-page-title-main">Radiosurgery</span> Surgical Specialty

Radiosurgery is surgery using radiation, that is, the destruction of precisely selected areas of tissue using ionizing radiation rather than excision with a blade. Like other forms of radiation therapy, it is usually used to treat cancer. Radiosurgery was originally defined by the Swedish neurosurgeon Lars Leksell as "a single high dose fraction of radiation, stereotactically directed to an intracranial region of interest".

Siemens Healthineers is a German company which provides healthcare services. It was spun off from its parent company Siemens in 2017, which retains a 75% stake. Siemens Healthineers is the parent company for several medical technology companies and is headquartered in Erlangen, Germany.

Elekta is a global Swedish company that develops and produces radiation therapy and radiosurgery-related equipment and clinical management for the treatment of cancer and brain disorders. Elekta has a global presence in more than 120 countries, with over 40 offices around the world and about 4,700 employees.

<span class="mw-page-title-main">Fast neutron therapy</span>

Fast neutron therapy utilizes high energy neutrons typically between 50 and 70 MeV to treat cancer. Most fast neutron therapy beams are produced by reactors, cyclotrons (d+Be) and linear accelerators. Neutron therapy is currently available in Germany, Russia, South Africa and the United States. In the United States, one treatment center is operational, in Seattle, Washington. The Seattle center uses a cyclotron which produces a proton beam impinging upon a beryllium target.

<span class="mw-page-title-main">Radiation treatment planning</span> In cancer or tumor treatments

In radiotherapy, radiation treatment planning (RTP) is the process in which a team consisting of radiation oncologists, radiation therapist, medical physicists and medical dosimetrists plan the appropriate external beam radiotherapy or internal brachytherapy treatment technique for a patient with cancer.

Varian Associates was one of the first high-tech companies in Silicon Valley. It was founded in 1948 by Russell H. and Sigurd F. Varian, William Webster Hansen, and Edward Ginzton to sell the klystron, the first vacuum tube which could amplify electromagnetic waves at microwave frequencies, and other electromagnetic equipment. Varian Associates split into three companies in 1999: Varian Medical Systems, Varian, Inc. and Varian Semiconductor.

<span class="mw-page-title-main">Tomotherapy</span> Type of radiation therapy

Tomotherapy is a type of radiation therapy treatment machine. In tomotherapy a thin radiation beam is modulated as it rotates around the patient, while they are moved through the bore of the machine. The name comes from the use of a strip-shaped beam, so that only one “slice” of the target is exposed at any one time by the radiation. The external appearance of the system and movement of the radiation source and patient can be considered analogous to a CT scanner, which uses lower doses of radiation for imaging. Like a conventional machine used for X-ray external beam radiotherapy, a linear accelerator generates the radiation beam, but the external appearance of the machine, the patient positioning, and treatment delivery is different. Conventional linacs do not work on a slice-by-slice basis but typically have a large area beam which can also be resized and modulated.

Image-guided radiation therapy is the process of frequent imaging, during a course of radiation treatment, used to direct the treatment, position the patient, and compare to the pre-therapy imaging from the treatment plan. Immediately prior to, or during, a treatment fraction, the patient is localized in the treatment room in the same position as planned from the reference imaging dataset. An example of IGRT would include comparison of a cone beam computed tomography (CBCT) dataset, acquired on the treatment machine, with the computed tomography (CT) dataset from planning. IGRT would also include matching planar kilovoltage (kV) radiographs or megavoltage (MV) images with digital reconstructed radiographs (DRRs) from the planning CT.

Particle therapy is a form of external beam radiotherapy using beams of energetic neutrons, protons, or other heavier positive ions for cancer treatment. The most common type of particle therapy as of August 2021 is proton therapy.

The CyberKnife system is a radiation therapy device manufactured by Accuray. The system is used to deliver radiosurgery for the treatment of benign tumors, malignant tumors and other medical conditions.

Intraoperative electron radiation therapy is the application of electron radiation directly to the residual tumor or tumor bed during cancer surgery. Electron beams are useful for intraoperative radiation treatment because, depending on the electron energy, the dose falls off rapidly behind the target site, therefore sparing underlying healthy tissue.

Minesh Prafulchandra Mehta is an American radiation oncologist and physician-scientist of Indian origin and Ugandan birth. He is currently deputy director and chief of radiation oncology at Miami Cancer Institute at Baptist Health South Florida.

<span class="mw-page-title-main">Brainlab</span>

Brainlab is a privately held German medical technology company headquartered in Munich, Bavaria. Brainlab develops software and hardware for radiotherapy and radiosurgery, and the surgical fields of neurosurgery, ENT and craniomaxillofacial, spine surgery, and traumatic interventions. Their products focus on image-guided surgery and radiosurgery, digital operating room integration technologies, and cloud-based data sharing. Brainlab is featured in the German media on topics such as the digitalisation of healthcare data and artificial intelligence in healthcare.

RaySearch Laboratories is a Swedish medical technology company that develops software used in radiation therapy of cancer. The company markets its products worldwide and has subsidiaries in the United States, Singapore, Belgium, France, Germany, and the United Kingdom.

<span class="mw-page-title-main">Jay Loeffler</span> American physician

Jay Steven Loeffler was an American physician at Massachusetts General Hospital, where he served as chair of the Department of Radiation Oncology since 2000. He was the Herman and Joan Suit Professor of Radiation Oncology and professor of neurosurgery at Harvard Medical School.

Anca-Ligia Grosu is a Romanian-German radiation oncologist and professor with a research focus on the development of personalized therapy in radiation oncology. She is chair of the Radiation Oncology Department at the University Medical Center Freiburg, Germany, and member of the German National Academy of Sciences Leopoldina.

References

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