Web review – 5 year old happy to go back to school

The parents of Katie Dodd, 5 years old and diagnosed with cancer just one year ago, are happy and proud to see their little girl going back to school to begin a new term.

Last September, doctors discovered a tumor pressing on Katie’s spinal chord. She could not move her legs anymore. They told her parents that she would need the most advanced form of radiotherapy: proton beam therapy. Since then, the little girl has completed 14 cycles of chemotherapy and travelled to the US for her state-of-the-art treatment, which is not yet available in the UK.

She’s been gradually building the strength back up in her legs in a bid to learn to walk again, despite her aggressive treatment. She has now been able to join her big brother and go back to Highfield Primary School, Farnworth, to start the new term. Her proud mum said: “It was just nice to take her and Joseph to school together because for the past year I’ve been looking forward to September to get some normality back.”

“She’s been doing really well over the summer. Her hair and eyelashes are even starting to grow back. She looked at me the other day and said, ‘Mummy, I look normal now’. She’s full of energy and not as fatigued any more. It’s like she’s a new girl.”

Katie will continue to work hard with physiotherapists and a dietician to get her strength and mobility back up. She will also have chest X-rays and MRI scans every 4 months to check for cancer cells. “She’s brilliant about it all and every day she tries to do something new for us, whether it’s sitting a different way or moving from one object to another. She loves to show off”, her Mom said.

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From our readers: Proton beam therapy: an alternative to now consider in Africa

There are certain cancer cases where surgery, chemotherapy and conventional photon radiotherapy are inappropriate treatment alternatives. In such cases, Proton Beam Therapy could just be the perfect option.

Proton beam therapy is a form of particle therapy which utilizes a beam of protons to irradiate cancerous tissues and possibly terminate abnormal proliferation of neoplasms while ensuring that the surrounding healthy tissues are not completely destroyed. In other words, it is a type of external beam radiotherapy which uses a particle accelerator to target the tumour with a beam of protons. These charged particles damage the Deoxyrinucleic acid (DNA) of the cells, ultimately causing their death or interfering with their capacity to proliferate.  Generally, both x-ray therapy and proton beams work on the principle of selective cell destruction.  The major advantage of proton beam therapy over conventional radiation therapy, however, is that the energy distribution of proton
s in proton therapy can be directed and deposited in tissue volumes designated by the radiologists and radiotherapist in a three-dimensional pattern from each beam used. This capability provides greater control and precision and therefore, superior management of treatment.

Fundemantal properties of the proton particle

Proton (p, 1H+) is a subatomic particle which has a relative charge of +1, 1.007593amu (atomic mass unit), a mean square radius of about 0.8fm and an approximate energy equivalent (MeV) of 938. It is simply a hadron composed of 3 valence quarks: two up quarks and one down quark which are held by strong forces which are mediated by gluons. All these properties make protons highly suitable for therapy.
Proton beam therapy treatment pattern

Generally, protons possess large masses. Due to their large masses, they tend to produce  little lateral side scatter in the tissue; the beam does not broaden much, stays focused on the tumour shape and delivers only low-dose side-effects to surrounding tissue. As the protons move through the body using the pencil beam scanning technology, they slow down, causing increased interaction with orbiting electrons.

Maximum interaction with electrons occurs as the protons approach their targeted stopping point. Thus, maximum energy is released within the designated cancer volume. The surrounding healthy cells receive significantly less injury than the cells in the designated volume.
As a result of protons’ dose-distribution characteristics, the radiotherapist can increase the dose to the malignant tumour while reducing the dose to surrounding normal tissues. This allows the dose to be increased beyond that which less-conformal radiation will allow. The overall effects lead to the potential for fewer harmful side effects, more direct impact on the tumour and increased tumour control.

The patient feels nothing during treatment. The minimized normal-tissue injury results in the potential for fewer effects following treatment, such as nausea, vomiting or diarrhoea. The patients’ experiences a better quality of life during and after treatment.
Biological changes associated with proton beam therapy

Usually when energized charged proton particles (usually in the range of 70 to 250 MeV) pass near orbiting electrons, the positive charge of the protons attracts the negatively charged electrons, pulling them out of their orbits. This is called ionization; it changes the characteristics of the atom and consequentially the character of the molecule within which the atom resides. This crucial change is the basis for the beneficial aspects of all forms of radiation therapy. Because of ionization, the radiation damages molecules within the cells, especially the DNA or genetic material. Damaging the DNA destroys specific cell functions, particularly the ability to divide or proliferate. Enzymes develop with the cells and attempt to rebuild the injured areas of the DNA; however, if damage from the radiation is too extensive, the enzymes fail to adequately repair the injury. While both normal and cancerous cells go through this repair process, a cancer cell’s ability to repair molec
ular injury is frequently inferior. As a result, cancer cells sustain more permanent damage and subsequent cell death than occurs in the normal cell population. This permits selective destruction of bad cells growing among good cells.

Applications of proton beam therapy
Proton therapy can be used to treat the following cancers:

  • Brain (acoustic neuroma, meningiomas, gliomas, pituitary adenomas, lipomas and other childhood brain tumors.)
  • Eye (oculoma melanoma, retinoblastoma)
  • Lung ( small-cell lung carcinoma and non-small cell lung carcinoma)
  • Spine (chordoma , chondrosarcoma)
  • Prostate (prostate adenocarcinoma)
  • Head and neck carcinomas
  • Pancreatic carcinomas

Advantages of proton beam therapy:

  • Proton beam therapy is generally preferred to the conventional photon radiotherapy because there is decreased dose to normal tissues and perfect localisation of beam to the site of the tumour.
  • Reduced side effects and complications.
  • Treating tumours close to critical organs like the spinal cord.
  • Increased cure rates.
  • Ability to retreat tumours after recurrences.
  •  Increasing safe dose delivered to the tumour.
  • Unlike x-rays, protons can treat cancers at complex locations and can also be manipulated to release their energy only when they reach their target which strongly suggests high level treatment accuracy.
  • Recent researches have reported that over 90 percent of patient treated with proton therapy presented positive results and also believe they made the right decision.

According to the World Health Organisation, about 70% of all cancer deaths occurred in low- and middle-income countries. It has also been estimated that deaths from cancer worldwide will rise to over 13.1 million in 2030. Consequently, it is imperative that proton therapy is considered in the treatment of patients presenting with malignant tumours as this form of radiotherapy offers high level accuracy and has also been effective in the palliation of cancer and extermination of neoplastic tissues. This article also suggests the pressing need to build a proton therapy center in Africa so that Africans suffering from cancers can be conveniently and comfortably treated within the continent. This project is quite feasible as a standard proton therapy center can be built with just $150 million. The proton therapy center will not just reduce death rates resulting from cancers across Africa, it will also provide meaningful employment opportunities for medical practitioners and allied health professionals.


Author : Prince Ameh Ogenyi

Oregon teen gets handcrafted bow

Oregon teen gets handcrafted bow from Indiana group she befriended during proton treatments at IU

A brown UPS truck had just departed from the Maupin household in Corvallis, Oregon. And Hannah Maupin was beaming as she carefully unwrapped the archery bow that had been custom made for her 2,300 miles away in Bloomington, Indiana.

There, weeks earlier, Hannah had selected a piece of black walnut from a tree planted by her great-grandfather nearly 100 years ago. The bowyer, Scott Mitchell, had carefully melded the black walnut with strips of maple and purple heartwood so the bow would be light enough for the 13-year-old to wield, and strong enough to endure the tension required to propel an arrow more than 150 feet per second.

For five Wednesday evenings last spring, Mitchell and other members of the Bloomington Archery Club provided Hannah with a welcome diversion from her cancer treatments at the Indiana University (IU) Health Proton Therapy Center. Proton beams were used to treat Hodgkin’s lymphoma that had re-appeared in the seventh grader’s chest and abdomen last year. Chemotherapy and stem cell replacement at Oregon Health & Science University had preceded 28 rounds of proton therapy.

“It was just really wonderful to break up the time,” said Hannah’s mom, Leah Maupin, who was born and raised in Bloomington. “These men made a daughter out of her.”

“I loved going there,” Hannah added. “ I wouldn’t want to miss it for anything.”

Hannah’s introduction to the bowmen of Bloomington came about during a conversation with one of her proton radiation technicians at IU.

“Frankie Willbanks asked me what my interests were, and I said, ‘Archery,’ ” Hannah recalled, telling Frankie she’d love to learn how to use a real bow and arrow. The tech knew that Steve Chambers, another IU proton patient, was an archery enthusiast. Chambers invited Hannah and Leah to visit a shoot at the archery club.

“The first time we drove out, I didn’t know what to expect,” Leah said. “They were doing an outside shoot. And Doug Fritch — he teaches archery to kids at the local Boys’ and Girls’ Clubs — he helped Hannah. And then Steve and Scott and others joined in to help find the right bow and teach her proper technique. Everyone just welcomed her.”

“The first day, we couldn’t find the right-size bow,” said Hannah. “They were all pretty heavy. I was horrible. I didn’t understand the [proper] form.

“The second day, I was more comfortable,” Hannah continued. “I had a bow that was lighter. And I hit the target that day. A ball hanging by a rope. I was thinking I would never hit that ball. But I did.”

Hannah never imagined she would find herself shooting her bow alongside the club regulars. “By the third visit, they let her up on the line to shoot with them,” Leah said. “Hannah loved it.”

During her final outing at the range, Hannah received a heartfelt farewell from the Bloomington archers. They presented Hannah with all the equipment she would need to keep shooting back in Corvallis: gloves, arm guard, quiver and arrows, with the custom bow to come.

Shortly after her return to her Oregon home, Hannah received a text message from Doug Fritch: “missed u at the shoot last sat. may your arrows fly true”

This weekend, with Scott Mitchell’s specially made bow in hand, Hannah will see how true her new arrows will fly. She’ll remember the proper form taught to her by the Bloomington bowmen. And she’ll remember the incredible kindness and generosity they showed to a teen who just had a wish to try her hand at archery.